Wireless communications system with parallel computing artificial intelligence-based distributive call routing

ABSTRACT

The present invention is directed to devices and methods that provide a user of a decentralized asynchronous parallel-configured wireless communication system for voice, data and live digital video streaming communication with the ability to select various communication paths and calling bandwidths as needed. The system uses a novel Time-Shared Full Duplex (TSFD) protocol for communications. The TSFD protocol allows the transmission of live digital video signals from one wireless device to another wireless device. The system provides local communication as well as optional links to external networks, and does not require a synchronous centralized switching center. It further provides secure operation, emergency notification and a way to collect revenue from the system, and allows for control of the operational state of the internal network and optional remote control of the operational state control of systems external to the network.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent applicationSer. No. 10/937,158 filed on Sep. 23, 2004, now U.S. Pat. No. 7,085,560which is a continuation-in-part of U.S. patent application Ser. No.10/063,283, filed on Apr. 8, 2002, now U.S. Pat. No. 6,842,617, which isa continuation-in-part of application Ser. No. 09/583,839, filed on May31, 2000, now U.S. Pat. No. 6,374,078.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.

BACKGROUND OF THE INVENTION

The invention relates generally to wireless communication systems and,particularly, to asynchronous wireless communication systems and devicesthat use radio frequencies for transmitting and receiving voice, dataand digital video signals within an internal communications network andto an external communication network. More particularly, the wirelesscommunication systems and devices operate with a novel Time-Shared FullDuplex (TSFD) asynchronous wireless communication protocol.

Wireless communication systems continue to grow, particularly in theareas of cellular and digital telephony and in paging systems. Wirelesssystems are especially popular in remote areas of the world that havelimited wired service because of the cost and difficulty of building awired infrastructure.

Traditional wireless communication systems such as cellular telephonesuse radio communication between a plurality of subscriber units withinthe synchronous wireless system and between subscriber units and thePublic Switched Telephone Network (PSTN) for calls that are outside ofthe wireless system. Most of these systems are characterized by wirelessmobile telephone units communicating synchronously with base stationsthat are connected to centralized mobile switching centers (MSC), whichare in turn connected to the PSTN. The centralized MSC performs a numberof functions, including routing wireless mobile units calls to othermobile units and wired (land-line) users and routing land-line calls tomobile units. At no time do these traditional wireless communicationssystems allow the handset to interface with the PSTN or other externalnetworks directly. The very core of the centralized wirelesscommunications theory requires every PSTN interface to be made throughan MSC. This is the only interface allowed.

Others' systems use point-to-point radio communication where mobileunits may communicate with other mobile units in the local area. Theysend origin and destination address formation and make use of squelchingcircuits to direct the wireless transmission to the correct destinationaddress. Most of these systems do not appear to provide a connection toa PSTN to send and receive calls outside the wireless network. This typeof system is decentralized, but because of the decentralization,collecting accurate billing information may be a problem.

Another form of wireless system is called a local multipointdistribution service (LDMS). In an LMDS system, a local area or cellthat is approximately 4 km in diameter contains fixed base stations,geographically distributed throughout the local area. One or moreantennas within the local area receive calls from the fixed basestations and relay the calls to other fixed base stations. In order forthe system to work, the fixed base stations must be within theline-of-sight path of at least one of the antenna units. The LDMS doesnot provide for mobile stations. Calls can only be routed within thelocal area and not to an external network. The system is essentially acentralized system within a local area. If one station is not within theline of sight of the antenna, it is effectively cut off fromcommunication.

There is a need for decentralized wireless communication systems thatare capable of handling voice, data and real-time digital streamingvideo communication that allow for a multiplicity of communicationpaths. It is desirable to have an ability to call on bandwidths asneeded, to provide local communication links, and to access links toexternal networks. Such networks may include public switch TelephoneNetworks, high speed-broadband cable, Internet, satellites and radioemergency networks. It is desirable to have a system that does notrequire a centralized switching center, provides for secure operation,allows for control of the operational state of the internal network,provides for emergency notification and provides a way to collectrevenue from the system. It is desirable to have elements within thesystem that allow for the remote controlled gathering of data, thepreprogrammed remote gathering of data, the remote controlling ofsystems external to the internal network, the remote controlling of theoperational state of systems external to the network and providingalternative paths for the relaying of signals. It is also desirable toprovide alternate direct-path communication between wireless devices andthe PSTN, without centralized switching or to provide alternatedirect-path communication between remotely placed wireless datacollection, reporting and remote control devices and the PSTN, alsowithout centralized switching. Such interfaces augment the conventionalpath routing and reduce call loads on any central communicationsinterface. It is also prudent to oversee the entire operational state ofthe network, its various components and signal routing devices with anArtificial Intelligence (AI)-based Distributive Routing System; anartificial “machine” learning software based logic manager prepared toassist and/or provide guidance during any unfortunate catastrophicfailure of major wireless infrastructure elements or during inevitablewireless set call connection failures due to peak hours call overloadingexperienced in a mature wireless system.

It is further desirable to have the AI system govern and administerparallel computing and system hardware operations during catastrophicfailures.

The present invention discloses such a system, herein referred to as theTime-Shared Full Duplex (TSFD) Parallel Computing ArtificialIntelligence-based Distributive Call Routing Wireless CommunicationSystem, or simply known in its short form the TSFD wirelesscommunication system. This system is particularly suitable for operationin rural areas where population density is low and wireless coverage iseither not currently available or inadequately serviced and wherelimited remote data gathering or remote control of systems or devicesvia wireless means is in operation. In the United States, the system issuitable for operation using the PCS spectrum (1850-1960 MHz or theWireless Communications Service (WCS) spectrum at 2320-2360 MHz that arelicensed by the Federal Communications Commission (FCC) or any othersuch frequency as may be determined suitable above 50 megahertz and lessthan 5 gigahertz. The wireless devices in the system incorporate amodular multi-mode capability to extend the wireless service area with apotential variety of standard wireless formats and bands, such as AMPS,D-AMPS, IS-95, IS-136, and GSM1900. This is an important feature becausewidespread deployment of a new wireless service takes appreciable time,and there are many other wireless standards from which to choose sincethese new customers may also venture into standard PCS or cellularmarkets.

With the advent of music, video and ringtone downloads into wirelesshandsets, camera pics, digital video capturing and sending, the world isready for a system where the Internet and computer transmission formats(asynchronous packets) can be enable in a mobile wireless handset. Soon,even the term “handset” will vanish as the world transitions to wirelessenabled microcomputers. Even the “modern” Personal Digital Assist (PDA)will become incapable of retaining all the information the users willexpect of tote with them. Music and I-Pod device technologies alone havepropelled the expansion of memory storage and file management to everhigher levels of proficiencies.

Overall, the US rural market and other major applications for the TSFDwireless communication system of the present invention are enormous. Afew of these include: emerging nations, especially those that presentlyhave limited or no telephone service, and those communities or groupsthat require a stand alone wireless communication network that can bequickly and cost-effectively deployed. Further; military, lawenforcement, disaster management or remote commercial installationsyield extremely viable market potentials.

The TSFD wireless communication system's attributes of low cost remotesensing and remote control of other devices and processing through suchversatile wireless devices is also critical to markets isolated frommajor urban economies and is ideally suited to developing nations hungerfor affordable technology.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects, and advantages of the presentinvention will become understood with regard to the followingdescription, appended claims, and accompanying drawings where:

FIG. 1 shows a deployment of two embodiments of the present TSFDwireless communication system;

FIG. 2 shows an embodiment of a relationship between adjacent macrocellsin a cellular topology;

FIG. 3 shows an embodiment of a relationship between adjacent microcellsin a macrocell topology;

FIG. 4 shows the radio frequency spectrum used by the present wirelesscommunication system;

FIG. 5 shows the radio frequency protocol used by the present wirelesscommunication system;

FIG. 6 shows a signal flow diagram of communication paths between a TSFDwireless handset in one microcell and a TSFD wireless ComDoc in anothermicrocell;

FIG. 7 shows a signal flow diagram of communication paths between a TSFDwireless handset and a TSFD wireless ComDoc in the same microcell;

FIG. 8 shows single channel TSFD voice or data frames and packetsbetween a TSFD wireless handset and a TSFD wireless ComDoc;

FIG. 9 shows four channels of TSFD CCAP data frames and packets betweena TSFD wireless handset and a TSFD wireless ComDoc;

FIG. 10 shows twelve channels of TSFD CCAP+ data frames and packetsbetween a TSFD wireless handset a TSFD wireless ComDoc;

FIG. 11 shows TSFD Integrated Direct Digital Transfer (IDDT) withmulti-channel voice and data frame and packets and inserted IDDT videostreaming between a TSFD handset and another TSFD handset;

FIG. 12 shows reference channel framing;

FIG. 13 shows a flow diagram for a call initiation channel and a callmaintenance channel;

FIG. 14 shows a block diagram of a TSFD wireless handset;

FIG. 15 shows a block diagram of a TSFD wireless ComDoc;

FIG. 16 shows optional features that may be added to the TSFD wirelessComDoc to expand its capability;

FIG. 17 shows examples of prefix codes for accessing TSFD wirelessComDoc functions;

FIG. 18 shows a block diagram of a TSFD wireless X-DatCom;

FIG. 19 shows a block diagram of a TSFD wireless PC-DatCom Card;

FIG. 20 shows of a block diagram of section “A” of a Parallel-configuredTSFD Signal Extender

FIG. 21 shows of a block diagram of section “B” of a Parallel-configuredTSFD Signal Extender;

FIG. 22 shows section “A” in a block diagram of a Parallel-configuredTSFD Network Extender;

FIG. 23 shows section “B” in a block diagram of a Parallel-configuredTSFD Network Extender;

FIG. 24 shows a diagram of possible signal paths between 3 microcellsand the TSFD communication frequency blocks utilized;

FIG. 25 shows a diagram of possible signal paths within a singlemicrocell and the TSFD communications frequency blocks utilized;

FIG. 26 shows the TSFD Broadcast Channel Designators

FIG. 27 shows the USA PCS Frequency Block Designations;

FIG. 28 shows TSFD Wireless Block Frequency Translation Table;

FIG. 29 shows the Artificial Intelligence-based Distributive RoutingVirtual macrocell LAN; and

FIG. 30 shows the Artificial Intelligence-based Distributive RoutingVirtual macrocell LAN.

DETAILED DESCRIPTION OF THE INVENTION

While this invention is susceptible of embodiment in many differentforms, there is shown in the drawings, and will be described herein indetail, specific embodiments thereof with the understanding that thepresent disclosure is to be considered as an exemplification of theprinciples of the invention and is not intended to limit the inventionto the specific embodiments illustrated.

The present invention is directed to devices and methods that provide auser of a decentralized asynchronous parallel-configured wirelesscommunication system for voice, data and live digital video streamingcommunication with the ability to select various communication paths andcalling bandwidths as needed. In a preferred embodiment, the system usesa novel Time-Shared Full Duplex (TSFD) protocol for communications. TheTSFD protocol allows the transmission of live digital video signals fromone wireless device to another wireless device by using the novelIntegrated Direct Data Transfer (IDDT) inserted in the TSFD protocol.The system provides local communication as well as optional links toexternal networks, and does not require a synchronous centralizedswitching center. It further provides secure operation, emergencynotification and a way to collect revenue from the system, and allowsfor control of the operational state of the internal network andoptional remote control of the operational state control of systemsexternal to the network. The operational state can be a static state inwhich the internal network is turned “ON” or “OFF” by a command, or theoperational state can by a dynamic state controlling of the functionsand operations of the systems. Communications between the variouselements of the TSFD wireless communication system are monitored andanalyzed by a system-resident and fully decentralized Parallel ComputingArtificial Intelligence-based Distributive Routing System, resulting inre-directing the communication paths to ensure call loads of theParallel-configured Signal Extender (PSE) and Parallel-configuredNetwork Extender (PNE) in the system do not exceed a predetermined limitfor each PSE or PNE, to optimize call loads of the PSE and PNE in thesystem, or to bypass any failed PSE or PNE in the system.

The decentralized asynchronous communication system of the presentinvention using the TSFD communication protocol, herein referred to asthe Time-Shared Full Duplex (TSFD) Parallel Computing ArtificialIntelligence-based Distributive Call Routing Wireless CommunicationSystem (or simply known as the TSFD wireless communication system),comprises six primary elements: (1) TSFD wireless handsets carried bymobile users; (2) TSFD wireless Personal Computer Data CommunicationsCards (TSFD wireless PC-DatCom Cards), also known as the PersonalComputer TSFD Multi-mode Wireless Access Cards, which may include a TSFDTelephone, PCS telephone, Wireless Fidelity (WiFi) links, Bluetoothlinks, and Red Fang Links; (3) TSFD wireless external datacommunications modules (TSFD wireless X-DatComs) for remotely gatheringdata or remotely controlling systems external to the device or to thenetwork; (4) TSFD wireless communications docking bays (TSFD wirelessX-DatComs) for providing alternative connections to internal or externalnetworks; (5) Parallel-configured TSFD Signal Extenders (PSEs) forrelaying TSFD wireless handset, TSFD wireless PC-DatCom Card, TSFDwireless ComDoc or X-DatCom signals; and (6) Parallel-configured TSFDNetwork Extenders (PNEs) for interconnecting signals from PSEs or otherPNEs. The first four elements are collectively known as the “wirelessdevices” or the “wireless set” for the TSFD wireless communicationsystem in the present invention. The PSEs and PNEs comprise theinfrastructure equipment that is located at antenna tower sites whileTSFD wireless ComDoc sets are located in a subscriber's home orbusiness, TSFD wireless X-DatComs comprise a varied array of remotelyplaced data gathering or remote control devices, TSFD wireless PC-DatComCards are a multiple network access “WiFi-like” card of PersonalComputers and TSFD wireless handsets provide the mainstay of the entireTSFD wireless communication system. For the system to be functional, itis not required to have all the six elements. The system can functionwith the PSEs, the PNEs and one or more of the wireless devices selectedfrom the TSFD wireless handsets, TSFD wireless PC-DatCom Cards, TSFDwireless X-DatComs, and TSFD wireless ComDocs. Alternatively, thewireless devices can communicate with each other directly without havingto communicate via a PSE and/or a PNE. The TSFD wireless devices sharethe same basic design. However, each wireless device can serve one ormore specific functions either as a handset, a ComDoc, an X-DatCom or aPC-DatCom Card as needed. Thus, a wireless device can have a singlefunction or have multiple functions. Unless otherwise stated, the TSFDwireless handset in the present disclosure can be a stand-alone wirelesshandset to be carried by a mobile user, or it can be associated withanother TSFD wireless device including the TSFD wireless PC-DatCom Card,the TSFD wireless X-DatCom, and the TSFD wireless ComDoc. What is meantby “associated” is that the device has a dual function. For example, aTSFD wireless handset associated with a TSFD wireless X-DatCom meansthat the device has both the functions of the TSFD wireless handset andthe functions of the TSFD X-DatCom combined in one device.

In further illuminating the TSFD wireless communication system, anyfixed location wireless component that is permanently fixed to alocation is known as a “TSFD Anchored Component” and all TSFD wirelessdevices which are not fixed to a permanent location are known as “TSFDMobile Devices.” Thus, the “TSFD Anchored Components” include the PSEsand the PNEs while the “TSFD Mobile Devices” include the TSFD wirelesshandsets, TSFD wireless ComDocs, TSFD wireless X-DatComs and TSFDwireless PC-DatCom Cards. Although the TSFD wireless X-DatComs areintended to be placed in a “fixed” location and are not intended to be“mobile” in certain applications, the TSFD wireless X-DatComs are stillconsidered as a “TSFD Mobile Device” since it is not fixed to apermanent location and can be moved easily if needed. These terms areessential in disclosures of operations and configurations of the TSFDE-911 Locator System described herein.

TSFD wireless handsets, TSFD wireless ComDocs, TSFD wireless X-DatComsand TSFD wireless PC-DatCom Cards are assigned standard telephonenumbers and are capable of placing and accepting calls with telephonesin the Public Switched Telephone Network (PSTN) through the PNEs. Callsthat are placed between TSFD wireless handsets, TSFD wireless ComDocs,TSFD wireless X-DatComs or TSFD wireless PC-DatCom Cards containedwithin the TSFD wireless network do not require routing through a PSTN.A TSFD wireless ComDoc interface device is designed to allow restrictedand private access to a TSFD wireless handset owner's home or officetelephone landline, thus creating a private link to the PSTN withoutnecessity of routing the wireless call through the PNE for an interfaceto the PSTN. TSFD wireless X-DatComs are varied in design to meetapplication needs but all have the capabilities of being placed inremote locations to gather data or control processes or devices externalto their own circuitry or to the network. TSFD wireless X-DatComs mayfacilitate a communication between other external network devicesequipped for ultra short range communication. These includeultra-wide-band, Red Fang, Bluetooth, or infrared spectrum protocols.Besides handling voice, data and the proprietary Integrated Direct DataTransfer (IDDT) for inserting a live video data stream into a standardTime Shared Full Duplex Protocol transmissions, the overall system alsosupports a wide variety of telephone features such as Internet access,cable modem access, bi-directional data transfer and variable bandwidthwireless calling channels. Direct connection to other external networksinclude: the PSTN, cable and other wireless protocols via the multi-modemodule in the Radio Frequency (RF) section of TSFD wireless handsets,TSFD wireless ComDocs, TSFD wireless X-DatComs and TSFD wirelessPC-DatCom Cards. The TSFD wireless handsets, TSFD wireless ComDocs, TSFDwireless PC-DatCom Cards and TSFD wireless X-DatComs may have WirelessFidelity (WiFi) options to establish wireless connectivity to otherdevices. Communication between the various elements of the TSFD wirelesscommunication system is monitored by a system-resident and fullydecentralized Parallel Computing Artificial Intelligence-basedDistributive Routing System.

The Parallel Computing Artificial Intelligence (AI)-based DistributiveRouting System comprises a group of computers of the Personal Computerstyle, with superior features and performance linked together by adedicated Local Area Network (LAN) and each computer having a ParallelComputing Artificial Intelligence software program to gather informationregarding timely calling data, routing and wireless device use historiesand to analyze the information for recommending or executing alternativecommunication paths within the entire system of the PSEs and the PNEduring excessive peak hours loading of the PNE or during a catastrophicfailure of any PSE or a PNE. Further, during such times as a failureoccurs and is detected by the AI system, within any fixed location or“Anchored” TSFD system, the Parallel Computing Artificial IntelligenceSystem is solely responsible for switching systems and subsystems tomaintain continuous and “seamless” operations within theseParallel-configured TSFD Infrastructure Components. The primary computerin the group would reside near, but not within, a PNE, with all othercomputers residing in the electronic component environmental housing ofeach PSE. All units share information and are programmed to operate as asingle “entity” via the TSFD LAN. Any single computer can bedisconnected and the system will still function. The term “parallelcomputing” is an operational function of the system, wherein a taskcould be distributed at the same time to several units for analysis.Failure of analysis is then less likely since the transactions arecomputed in “parallel”. Resulting data (answers to the transaction) areutilized by the first system to complete the task.

The Parallel Computing Artificial Intelligence System may furtherprovide reports the day's gathered information to each of the other PSEAI Computers for comparative analysis and the making of logicalsuggestions to the TSFD wireless handsets, TSFD wireless ComDocs, TSFDwireless PC-DatCom Cards and TSFD wireless X-DatComs operating withinthe system. The Parallel Computing Artificial Intelligence System isprogrammed to gather relevant data from remotely placed TSFD wirelessX-DatCom modules by means of a wireless protocol established foroperations of the system. The Time-Shared Full Duplex (TSFD) wirelessprotocol is established for operations of the system interfaced with anetwork including for example, but is not limited to, Public SwitchTelephone Network lines, a fiber optic communication link, a coaxialcable, a public TCP/IP network, a directional emergency tower to towermicrowave link, a satellite communication link, a ComDoc routed to otherdestinations and data collection devices selected by the ParallelComputing Artificial Intelligence System.

The enhanced 911 (E-911) wireless device locator of the TSFD wireless“Mobile” devices is supported and shared equally by the ParallelComputing Artificial Intelligence-based System and the residentoperations computer within the PNE. Should one of these systems fail inthe location process, the other assumes the task.

An embodiment of the present invention discloses a method of operating aparallel-configured TSFD wireless communication system for voice anddata signals, the system comprising one or more macrocells and eachmacrocell having a plurality of microcells. The method comprises:establishing a local communication path for transmitting and receivingsignals between a local TSFD wireless device and a remotely placed localTSFD wireless device within a same microcell via a PSE; establishing anextended communication path for transmitting and receiving signalsbetween an extended TSFD wireless device and a remotely placed extendedTSFD wireless device located within different microcells positionedwithin a same macrocell via PSEs and a PNE; establishing a distantcommunication path for transmitting and receiving signals between adistant TSFD wireless device and a remotely placed distant TSFD wirelessdevice located within different microcells positioned within differentmacrocells via PSEs and PNEs; and asynchronously transmitting andreceiving half-duplex signals over the communication paths using pairsof assigned communication path frequencies stabilized by a GPS-basedfrequency reference source. The TSFD wireless device can be selectedfrom the group consisting of TSFD wireless handsets, TSFD wirelessPC-DatCom Cards, TSFD wireless DatComs, and TSFD wireless ComDocs. Thecommunication paths can be monitored and analyzed by a system-residentand decentralized Parallel Computing Artificial Intelligence-basedDistributive Routing System, resulting in re-directing the communicationpaths to ensure call loads of the PSE and PNE in the system do notexceed a predetermined limit for each PSE or PNE, to optimize call loadsof the PSE and PNE in the system, or to bypass any failed PSE or PNE inthe system. The step of establishing a local communication path maycomprise: transmitting signals from the local TSFD wireless devices tothe PSE; receiving and re-transmitting signals by the PSE to the localTSFD wireless devices; and receiving signals from the PSE by the localTSFD wireless devices. The step of establishing an extendedcommunication path may comprise: transmitting signals from the extendedTSFD wireless devices to the PSE; receiving and re-transmitting signalsfrom the extended TSFD wireless devices by the PSE to a PNE; receivingand re-transmitting signals from the PSE by the PNE to the PSE;receiving and retransmitting signals from the PNE by the PSE to theextended TSFD wireless devices; and receiving signals from the PSE bythe extended TSFD wireless devices. The step of establishing a distantcommunication path may comprise: transmitting signals from the distantTSFD wireless devices to the PSEs; receiving and re-transmitting signalsfrom the distant TSFD wireless devices by the PSEs to the PNEs;receiving and re-transmitting signals from the PSEs by a PNE to anotherPNE; receiving and re-transmitting signals from a PNE by another PNE toPSEs; receiving and re-transmitting signals from PNEs by PSEs to thedistant TSFD wireless devices; and receiving signals from PSEs by thedistant TSFD wireless devices. The step of receiving and re-transmittingsignals by a PNE to another PNE may be selected from, but is not limitedto, the group consisting of transmitting signals over a Public SwitchTelephone Network (PSTN), transmitting signals over a fiber opticcommunication link, transmitting signals over a coaxial cable,transmitting signals over a public TCP/IP network, and transmittingsignals over a satellite communication link. Half of the signalsreceived by a PSE in a microcell may be transmitted by TSFD wirelessdevices in the microcell in a low radio frequency band and half of thesignals received by the PSE in a macrocell may be transmitted by a PNEin the macrocell in a low radio frequency band. Half of the signalstransmitted by a PSE in a microcell may be received by a TSFD wirelessdevice in the microcell in a high radio frequency band and half of thesignals transmitted by the PSE in a macrocell may be received by a PNEin the macrocell in a high radio frequency band. The transmitting andreceiving signals between a TSFD wireless device or PSE or a PNE andanother TSFD wireless device or PSE or PNE may be conductedasynchronously with a TSFD protocol. The step of establishing a localvoice communication path between a local TSFD wireless device and aremotely placed local TSFD wireless device may comprise using two fixedfrequencies in a sub-band spectrum for establishing a local voicechannel. The step of establishing a local data communication path undera four channel Contiguous Channel Acquisition Protocol between a localTSFD wireless device and a remotely placed local TSFD wireless devicemay comprise using two fixed frequencies having a bandwidth of fourtimes the bandwidth of a local voice channel by combining fourcontiguous voice channels. The step of establishing a local datacommunication path under a twelve channel Contiguous Channel AcquisitionProtocol Plus between a local TSFD wireless device and a remotely placedlocal TSFD wireless device under a twelve channel Contiguous ChannelAcquisition Protocol Plus may comprise using two fixed frequencieshaving a bandwidth of twelve times the bandwidth of a local voicechannel by combining twelve continuous voice channels. The step ofestablishing an extended voice communication path may comprise usingfour fixed frequencies in a sub-band spectrum for establishing anextended voice channel. The step of establishing an extended datacommunication path under a four channel Contiguous Channel AcquisitionProtocol between an extended TSFD wireless device and a remotely placedextended TSFD wireless device may comprise using four fixed frequencieshaving a bandwidth of four times the bandwidth of an extended voicechannel by combining four contiguous voice channels. The step ofestablishing an extended data communication path under a twelve channelContiguous Channel Acquisition Protocol Plus between an extended TSFDwireless device and a remotely placed extended TSFD wireless device maycomprise using four fixed frequencies having a bandwidth of twelve timesa bandwidth of an extended voice channel by combining twelve contiguousvoice channels. The step of establishing a distant voice communicationpath may comprise using four fixed frequencies in a sub-band spectrumfor establishing a distant voice channel. The step of establishing adistant data communication path under a four channel Contiguous ChannelAcquisition Protocol between a distant TSFD wireless device and aremotely placed distant TSFD wireless device may comprise using fourfixed frequencies having a bandwidth of four times the bandwidth of adistant voice channel by combining four contiguous voice channels. Thestep of establishing a distant data communication path under a twelvechannel Contiguous Channel Acquisition Protocol Plus between a distantTSFD wireless device and a remotely placed distant TSFD wireless devicemay comprise using four fixed frequencies having a bandwidth of twelvetimes a bandwidth of a distant voice channel by combining twelvecontiguous voice channels. The method may further comprise establishinga communication path for transmitting and receiving signals between aTSFD wireless device and an external network via a PSE and a PNEconnected to the external network. The external network may be selectedfrom, but is not limited to, the group consisting of a Public SwitchTelephone Network (PSTN), a fiber optic communication link, a coaxialcable, a public TCP/IP network, and a satellite communication link. Themethod may further comprise establishing a communication path fortransmitting and receiving signals between a TSFD wireless device and anexternal network via a TSFD wireless device connected to the externalnetwork. The external network may be selected from, but is not limitedto, the group consisting of a Public Switch Telephone Network (PSTN), afiber optic communication link, a coaxial cable, a public TCP/IPnetwork, and a satellite communication link. The method may furthercomprise establishing a communication path for transmitting andreceiving signals between a TSFD wireless device and a localcommunication network. The local communication network may be selectedfrom, but is not limited to, the group consisting of TSFD wirelesshandsets associated with TSFD wireless ComDocs, TSFD wireless PC-DatComCards, TSFD wireless X-DatComs or other TSFD wireless handsets furtherassociated with local extension telephones connected to a Public SwitchTelephone Network via a TSFD wireless PC-DatCom Card, a TSFD wirelessComDoc, an infrared link, a Red Fang link, a Bluetooth link, a wiredcomputer local area network, a wireless local area computer network, asecurity system and another such TSFD wireless set links.

Another embodiment of the present invention is a method of operating awireless communication system for voice and data signals, the systemcomprising one or more macrocells and each macrocell having a pluralityof microcells. The method comprises: establishing a local communicationpath for transmitting and receiving signals between a local TSFDwireless device and a remotely placed local TSFD wireless device withina same microcell comprising: receiving and transmitting signals betweenthe local TSFD wireless device and a PSE; receiving and transmittingsignals between the PSE, the local TSFD wireless device and the remotelyplaced local TSFD wireless device; and receiving and transmittingsignals between the remotely placed local TSFD wireless device and thePSE; establishing an extended communication path for transmitting andreceiving signals between an extended TSFD wireless device and aremotely placed extended TSFD wireless device within differentmicrocells positioned within a same macrocell comprising” transmittingand receiving signals between the extended TSFD wireless device and afirst PSE; transmitting and receiving signals between the first PSE anda PNE; transmitting and receiving signals between the PNE and a secondPSE, transmitting and receiving signals between the second PSE and theremotely placed extended TSFD wireless device; and transmitting andreceiving signals between the remotely placed extended TSFD wirelessdevice and the second PSE; establishing a distant communication path fortransmitting and receiving signals between a distant TSFD wirelessdevice and a remotely placed distant TSFD wireless device withindifferent microcells positioned within different macrocells comprising”transmitting and receiving signals between the distant TSFD wirelessdevice and a first PSE; transmitting and receiving signals between thefirst PSE and a first PNE; transmitting and receiving signals betweenthe first PNE and a second PNE; transmitting and receiving signalsbetween the second PNE and a second PSE; transmitting and receivingsignals between the second PSE and the remotely placed distant TSFDwireless device; transmitting and receiving signals between the remotelyplaced distant TSFD wireless device and the second PSE; andasynchronously transmitting and receiving half-duplex signals over thecommunication paths using pairs of assigned communication pathfrequencies stabilized by a GPS-based frequency reference source. TheTSFD wireless device can be selected from the group consisting of: TSFDwireless handsets, TSFD wireless PC-DatCom Cards, TSFD wireless DatComs,and TSFD wireless ComDocs. The communication paths can be monitored andanalyzed by a system-resident and decentralized Parallel ComputingArtificial Intelligence-based Distributive Routing System, resulting inre-directing the communication paths to ensure call loads of the PSE andPNE in the system do not exceed a predetermined limit for each PSE orPNE, to optimize call loads of the PSE and PNE in the system, or tobypass any failed PSE or PNE in the system. The step of transmittingsignals between the first PNE and the second PNE may be selected from,but is not limited to, the group consisting of transmitting signals overa Public Switch Telephone Network (PSTN), transmitting signals over afiber optic communication link, transmitting signals over a coaxialcable, transmitting signals over a public TCP/IP network, andtransmitting signals over a satellite communication link. The steps oftransmitting signals from the TSFD wireless device to the PSE may be ina low radio frequency band and transmitting signals from the PSE to theTSFD wireless device may be in a high radio frequency band, transmittingsignals from the PSE to the PNE may be in a high radio frequency bandand transmitting signals from the PNE to the PSE may be in the low radiofrequency band, and transmitting signals between the PNE may be on ahigh data rate system backbone. Half of the signals received by a PSE ina microcell may be transmitted by TSFD wireless devices in the microcellin a low radio frequency band and half of the signals received by thePSE in a microcell may be transmitted by a PNE in the macrocell in a lowradio frequency band. Half of the signals transmitted by a PSE in amicrocell may be received by TSFD wireless devices in the microcell in ahigh radio frequency band and half of the signals transmitted by the PSEin a microcell may be received by a PNE in the macrocell in a high radiofrequency band. The transmitting and receiving signals between a TSFDwireless device and another TSFD wireless device may be conductedasynchronously with transmitting signals between other TSFD wirelessdevices. The steps of transmitting and receiving signals may compriseusing Frequency Division Multiple Access techniques for determiningsub-bands in the high and low radio frequency bands. The steps oftransmitting and receiving signals may comprise using Gaussian MinimumShift Keying modulation for producing a radio frequency waveform. Thetransmitting and receiving signals from a TSFD wireless device andanother TSFD device may comprise a primary mode and an optionalsecondary mode of operation. The primary mode of operation may comprisethe TSFD wireless frequency protocol. The secondary mode of operationmay be selected from, but is not limited to, the group of wirelessprotocols consisting of AMPS, D-AMPS, IS-95, IS-136, and GSM1900. Themethod may further comprise controlling an operational state of the TSFDwireless communication system by transmitting an operational statecommand to a PNE from the TSFD wireless device. The step of establishinga local voice communication path between a local TSFD wireless deviceand a remotely placed local TSFD wireless device may comprise using twofixed frequencies in a sub-band spectrum for establishing a local voicechannel. The step of establishing a local data communication path undera four channel Contiguous Channel Acquisition Protocol between a localTSFD wireless device and a remotely placed local TSFD wireless devicemay comprise using two fixed frequencies having a bandwidth of fourtimes the bandwidth of a local voice channel by combining fourcontiguous voice channels. The step of establishing a local datacommunication path under a twelve channel Contiguous Channel AcquisitionProtocol Plus between a local TSFD wireless device and a remotely placedlocal TSFD wireless device may comprise using two fixed frequencieshaving a bandwidth of twelve times the bandwidth of a local voicechannel by combining twelve contiguous voice channels. The step ofestablishing an extended voice communication path may comprise usingfour fixed frequencies in a sub-band spectrum for establishing anextended voice channel. The step of establishing an extended datacommunication path under a four channel Contiguous Channel AcquisitionProtocol between an extended TSFD wireless device and a remotely placedextended TSFD wireless device may comprise using four fixed frequencieshaving a bandwidth of four times the bandwidth of an extended voicechannel by combining four contiguous voice channels. The step ofestablishing an extended data communication path under a twelve channelContiguous Channel Acquisition Protocol Plus between an extended TSFDwireless device and a remotely placed extended TSFD wireless device maycomprise using four fixed frequencies having a bandwidth of twelve timesthe bandwidth of an extended voice channel by combining twelvecontiguous voice channels. The step of establishing a distant voicecommunication path may comprise using four fixed frequencies in asub-band spectrum for establishing a distant voice channel. The step ofestablishing a distant data communication path under a four channelContiguous Channel Acquisition Protocol between a distant TSFD wirelessdevice and a remotely placed distant TSFD wireless device may compriseusing four fixed frequencies having a bandwidth of four times thebandwidth of a distant voice channel by combining four contiguous voicechannels. The step of establishing a distant data communication pathunder a twelve channel Contiguous Channel Acquisition Protocol Plusbetween a distant TSFD wireless device and a remotely placed distantTSFD wireless device may comprise using four fixed frequencies having abandwidth of twelve times the bandwidth of a distant voice channel bycombining twelve contiguous voice channels. The method may furthercomprise establishing a communication path for transmitting andreceiving signals between a TSFD wireless device and an external networkvia another TSFD wireless device connected to the external network. Theexternal network may be selected from, but is not limited to, the groupconsisting of a Public Switch Telephone Network, a fiber opticcommunication link, a coaxial cable, a public TCP/IP network, and asatellite communication link. The transmitting signals may comprisedigitizing, buffering and encoding voice frames and transmitting thevoice frames in packets at a date rate that is at least twice thatrequired for real-time decoding, whereby transmitting time requires lessthan half of real time, and receiving signals may comprise receiving anddecoding the voice frame packets at a data rate that is equal to thatrequired for real-time decoding, whereby receiving time requires lessthan half of real-time. The method may further comprise transmitting andreceiving information over a reference channel for providing a TSFDwireless device and another TSFD wireless device with time and dateinformation, microcell and macrocell identification code, attentioncodes, and broadcast text messages. The method may further comprisetransmitting and receiving information over a call initiation channelfor handling TSFD wireless device and receiving Mobile TSFD wirelessdevice initial registration, periodic registration, authorization andshort identification (ID) assignment, call requests, call frequencyassignment, call progress prior to voice and data channel use, andacknowledgement. The method may further comprise transmitting andreceiving information over a call maintenance channel for callcompletion, call request, 911 position report, call handoff frequency,call waiting notification, voice message notification, text messagenotification, and acknowledgement.

In a further embodiment of the present invention, a TSFD wirelesscommunication system for voice and data signals comprises: one or moremacrocells and each macrocell having a plurality of microcells; a TSFDwireless set comprising one or more TSFD wireless devices selected fromTSFD wireless handsets, TSFD wireless ComDocs, TSFD wireless X-DatComs,and TSFD wireless PC-DatCom Cards; a PSE located in the microcell; a PNElocated in the macrocell; means for establishing a local communicationpath for transmitting and receiving signals between a local TSFDwireless device and a remotely placed local TSFD wireless device withina same microcell via a PSE; means for establishing an extendedcommunication path for transmitting and receiving signals between anextended TSFD wireless device and a remotely placed extended TSFDwireless device located within different microcells positioned within asame macrocell via PSE and a PNE; means for establishing a distantcommunication path for transmitting and receiving signals between adistant TSFD wireless device and a remotely placed distant TSFD wirelessdevice located within different microcells positioned within differentmacrocells via PSE and PNE; means for asynchronously transmitting andreceiving half-duplex signals over the communication paths using pairsof assigned communication path frequencies stabilized by a GPS-basedfrequency reference source; and a system-resident and decentralizedParallel Computing Artificial Intelligence-based Distributive RoutingSystem for monitoring and analyzing the transmitted and received signalsover the communication paths, resulting in re-directing thecommunication paths to ensure call loads of the PSE and PNE in thesystem do not exceed a predetermined limit for each PSE or PNE, tooptimize call loads of the PSE and PNE in the system, or to bypass anyfailed PSE or PNE in the system. The means for establishing a localcommunication path for transmitting and receiving signals between alocal TSFD wireless device and a remotely placed local TSFD wirelessdevice within a same microcell via a PSE may comprise: a local TSFDwireless device for encoding voice and data frame packets andtransmitting these packets as radio frequency signals in a low radiofrequency band; a PSE for receiving, amplifying, and shifting afrequency of the local TSFD wireless device and the remotely placedlocal TSFD wireless device's signals in the low radio frequency band toa high radio frequency band and transmitting the high radio frequencyband signals; a local TSFD wireless handset for receiving signals in thehigh radio frequency band from the PSE and decoding the received signalsinto a voice and data frame packet; the local TSFD wireless device forencoding voice and data frame packet and transmitting these packets asradio frequency signals in a low radio frequency band; and the localTSFD wireless device for receiving signals in the high radio frequencyband from the PSE and decoding the received signals into a voice anddata frame packet. The means for establishing an extended communicationpath for transmitting and receiving signals between an extended TSFDwireless device and a remotely placed extended TSFD wireless devicewithin different microcells positioned within a same macrocell via PSEand a PNE may comprise: an extended TSFD wireless device for encodingvoice and data frame packet and transmitting these packets as radiofrequency signals in a low frequency band; a first PSE for receiving,amplifying, and shifting a frequency of the extended TSFD wirelessdevice signals in the low radio frequency band to a high radio frequencyband and transmitting the high radio frequency band signals from thefirst PSE to the PNE; the PNE for receiving, amplifying, and shifting afrequency of PSE signals in the high radio frequency band to a low radiofrequency band and transmitting the low radio frequency band signalsfrom the PNE to selected PSEs; a second PSE for receiving, amplifying,and shifting a frequency of the PNE signals in the low frequency band toa high radio frequency band and transmitting the high radio frequencyband signals; a remotely placed extended TSFD wireless device forreceiving the second PSE signals in the high radio frequency band anddecoding the received signals into a voice and data frame packet; theremotely placed extended TSFD wireless device for encoding voice anddata frame packet and transmitting these packets as radio frequencysignals in a low frequency band; the second PSE for receiving,amplifying, and shifting a frequency of the TSFD wireless handsetsignals in the low radio frequency band to a high radio frequency bandand transmitting the high radio frequency band signals from the secondPSE to the PNE; the first PSE for receiving, amplifying, and shifting afrequency of the PNE signals in the low frequency band to a high radiofrequency band and transmitting the high radio frequency band signals;and the extended TSFD wireless device for receiving the first PSEsignals in the high radio frequency band and decoding the receivedsignals into a voice and data frame packet. The means for establishing adistant communication path for transmitting and receiving signalsbetween a distant TSFD wireless device and a remotely placed distantTSFD wireless device within different microcells positioned withindifferent macrocells via PSEs and PNEs may further comprise: a first PNEfor receiving, amplifying first PSE signals from a first PSE andtransmitting the first PSE signals to a second PNE over a dedicatedcommunication link; and the second PNE for receiving and shifting afrequency of first PSE signals in the high radio frequency band to a lowradio frequency band and transmitting the low radio frequency bandsignals from the second PNE to the second PSE. A microcell may comprisea geographical area containing one or more wireless devices (selectedfrom TSFD wireless handsets, TSFD wireless TSFD wireless ComDocs, TSFDwireless X-DatComs, and TSFD wireless TSFD wireless PC-DatCom Cards) anda PSE, and a macrocell may comprise a geographical area containingbetween one and twenty one microcells, and a PNE. The TSFD wirelesshandset may comprise external communication paths for transmitting andreceiving signals between the TSFD wireless device and an externalcommunication network to enable TSFD wireless device and devicesassociated with another TSFD wireless device to connect to the externalnetwork through the TSFD wireless device. The external network may beselected from, but is not limited to, the group consisting of a PublicSwitch Telephone Network, a fiber optic communication link, a coaxialcable, a public TCP/IP network, and a satellite communication link. TheTSFD wireless device may comprise local communication paths fortransmitting and receiving signals between the TSFD wireless device anda local communication network. The local communication network may beselected from the group consisting of TSFD wireless handsets associatedwith TSFD wireless communication docking bays, TSFD wireless handsetassociated with TSFD wireless PC-DatCom Cards, TSFD wireless handsetsassociated with TSFD wireless communication docking bays, TSFD wirelesscommunication docking bays associated with TSFD wireless X-DatComs, orTSFD wireless X-DatComs associated with other TSFD wireless X-DatComs,local extension telephones connected to a Public Switch TelephoneNetwork via the TSFD wireless X-DatCom, an infrared link, a Red FangLink, a Bluetooth link, a WiFi link, a wired computer local areanetwork, a wireless local area computer network, a security system andanother TSFD wireless handset link. The TSFD wireless device maycomprise: a processor for controlling TSFD wireless device operationcomprising a digital signal processor, a controller, and memory; a userinterface comprising, but is not limited to, a display, a keypad, visualindication or, audio annunciator, microphone and speaker, a vocoderconnected to a microphone and speaker interface, a power manager,battery and power source; an external data interface; connections forfixed telephone handset extensions; connections to a Public SwitchTelephone Network; a primary mode transceiver having a transmitter andtwo receivers connected to an omni-directional antenna for use with aTSFD protocol; and an optional secondary mode transceiver for providingservice using another standard protocol. The TSFD wireless device mayinclude an optional interface connection such as, but is not limited to,an infrared data interface, an external keyboard interface, an externalmonitor interface, a video camera interface, A WiFi Link, a Red Fanglink, a Bluetooth interface, a LAN/cable modem interface, an E-911position locator interface, a GPS position locator interface, a harddrive interface, a CD/DVD drive interface, a Public Switch TelephoneNetwork modem interface, or an external antenna interface. The TSFDwireless handsets, TSFD wireless PC-DatCom Cards, TSFD wirelessX-DatComs and TSFD wireless ComDocs may transmit voice and data packetshalf of the time and receive voice and data packets half of the timewhen in use. In an embodiment, a TSFD wireless device in the TSFDwireless system communicates directly with another TSFD wireless deviceusing the TSFD wireless protocol without communicating via a signal ornetwork extender.

In a further embodiment, the present invention discloses a wirelessdevice for use in an asynchronous wireless communication system using anasynchronous wireless protocol as its primary mode of operation, thedevice comprises: a processor for controlling wireless device operationcomprising a digital signal processor, a controller, and memory; a userinterface comprising a display, a keypad, visual indication or, audioannunciator, microphone and speaker, a vocoder connected to a microphoneand speaker interface; a power manager, battery and power source; anexternal data interface; connections for fixed telephone handsetextensions; connections to a Public Switch Telephone Network; a primarymode transceiver having a transmitter and two receivers connected to anomni-directional antenna for use with an asynchronous wireless protocol;and an optional roaming transceiver operating in a secondary mode forproviding service using another standard protocol selected from thegroup consisting of wireless protocols and landline protocols. In apreferred embodiment the wireless protocol for the secondary mode isselected from the group consisting of AMPS, D-AMPS, IS-95, IS-136, andGSM1900. The wireless device may further include an interface connectionto an infrared data interface, an external keyboard interface, anexternal monitor interface, a video camera interface, A WirelessFidelity (WiFi) Link, a Red Fang link, a Bluetooth interface, aLAN/cable modem interface, an enhanced 911 (E-911) position locatorinterface, a GPS position locator interface, a hard drive interface, aCD/DVD drive interface, a Public Switch Telephone Network modeminterface, or an external antenna interface. The wireless device of eachhas its unique telephone number in non-volatile memory and a uniqueelectronic serial number in permanent memory. In another preferredembodiment, the wireless device is a TSFD wireless device wherein theprimary asynchronous wireless protocol is Time-Shared Full Duplex (TSFD)wireless protocol. The TSFD wireless device can exercise static statecontrol or dynamic state control. The TSFD wireless device may also havean enhanced-911 (E-911) locator. In an embodiment, the wireless deviceis a wireless handset carried by a mobile user. The handset ispreferably a TSFD wireless handset which performs as a wireless hub ormodem for WiFi, TSFD CCAP or CCAP+ to allow the handset and a laptopcomputer to create a link to any data source or external network throughthe wireless handset. The TSFD wireless handset may perform standard PCSvideo, music and ringtone downloads within a TSFD wireless communicationsystem or from other networks while operating within the roamingtransceiver mode. The TSFD wireless handset may further comprise adigital camera to capture images to be sent to, received and displayedby another TSFD wireless device through an Integrated Direct DataTransfer (IDDT) sub-protocol of the TSFD protocol, the captured images.The images can be stereoscopic images when captured by a plurality ofdigital cameras associated with the TSFD wireless handset and thestereoscopic images can be displayed by a viewing device attached to thereceiving TSFD wireless device such as a virtual reality headset. Inanother embodiment, the wireless device is a Communication Docking Bay(ComDoc) placed at a user's home or business for providing alternativeconnections for other wireless devices to internal or external networks,an External Data Communication Module (X-DatCom) which has multipleexternal interface paths and is remotely operated or preprogrammed to beremotely placed to gather data, send or receive data, transfer data on apredetermined schedule, or a Personal Computer Data Communication Card(TSFD PC-DatCom Card) suitable for plugging into a personal computer,preferably a laptop computer, to send and receive signals with any TSFDwireless device within the wireless communication system. The X-DatComcan be a fixed-base wireless set having its own telephone number,functions as a handset-to-external network relay system, serves as ahome-based high speed access device to wireless broadband Internetservice for home computers, serves as a remote access interface devicefor high-speed wireless broadband Internet service betweenhandset-laptop computer combinations and home installed broadbandInternet connection; or serves as a wireless connection to PublicSwitched Telephone Network (PSTN). In an embodiment, the wirelessdevices of the present can communicate with each other using theasynchronous protocol, preferably the TSFD asynchronous protocol,without having to communicate via a signal extender or a networkextender.

In yet another embodiment of the present invention discloses aTime-Shared Full Duplex (TSFD) asynchronous wireless communicationsprotocol for use in a TSFD wireless communication system, wherein: thewireless protocol utilizes broadband radio frequency (RF) spectrum withlow band reserved for Parallel-configured Signal Extender (PSE) receivefrequencies and high band for PSE transmit frequencies; half of eachband is reserved for signals between the PSEs and a TSFD device, theother half of each band is reserved for signals between PSEs andParallel-configured Network Extenders (PNEs) with duplex filtering and aseparation of from 10 to 80 megahertz between the low band and the highband such that the PSE can simultaneously receive and transmit signalswithout compromising receiver sensitivity; voice data channels (VDCs)containing voice or data frames and packets are used to carry voice/datacall traffic in the wireless system wherein the VDC is a local VDCbetween a local wireless device and a remotely place local wirelessdevice within a same microcell, an extended VDC between an extendedwireless device and a remotely placed extended wireless device indifferent microcell in a same macrocell, or a distant VDC between adistant wireless device and a remotely placed wireless device in adifferent microcell in a different macrocell; the RF spectrum is dividedinto control and data channels wherein each channel comprises atransmit/receive pair of frequencies separated by 10 to 80 megahertz;signal transmission is un-multiplexed wherein compressed signals aresent continuously from multiple channels and decompressed and playedback when received; the wireless protocol includes an Integrated DirectData Transfer (IDDT) sub-protocol wherein the TSFD protocol can betransitioned to the IDDT sub-protocol to allow one-directional transferof digital data from one wireless device to be received by anotherwireless device; the TSFD wireless protocol includes reference channel(RC) framing; the TSFD wireless protocol includes a call initiationchannel (CIC) and a call maintenance channel (CMC); and the TSFDwireless protocol includes an optional Red Fang sub-protocol using anUltra-Wide Band—Ultra Low Power operated at 5 Gigahertz. Bandwidth whichcan be varied as necessary and with communications limited to about 3feet distance with line of sight as the optimum operating mode. Thedigital data transferred by the IDDT sub-protocol are preferably livestreaming digital video signals. The TSFD wireless protocol allows acomponent of the TSFD wireless communication system an operational sateof the wireless communication system by transmitting an operationalstate control command, wherein the operational state control is a staticstate control or a dynamics state control. In an embodiment, the TSFDwireless protocol allows for the collection of revenue within thewireless system. Examples of methods for collecting revenue aredisclosed in U.S. Pat. Nos. 6,141,531 and 6,842,617. In yet anotherembodiment, the TSFD wireless protocol allows for the migration of anyTSFD wireless device off of the TSFD wireless network. The TSFD wirelessprotocol allows for the utilization of radio frequencies other than thestandard United States of America PCS bands available to wirelessservice providers, wherein any frequency from 50 megahertz to 5gigahertz, as available where law allows. The TSFD wireless protocol canalso allow the communication of a TSFD wireless device to another TSFDwireless device without a network extender or signal extender whereinthe full spectrum of the radio frequencies are received and transmitteddirectly from a TSFD wireless device to another TSFD wireless device.

In still a further embodiment, the present invention discloses anasynchronous monocell wireless communication system comprising aParallel-configured Signal Extender (PSE) and one or more wirelessdevices selected from the group consisting of: wireless handsets,external data communication modules (X-DatCom), personal computer datacommunication cards (PC-DatCom Cards), and communication docking bays(ComDocs), wherein the wireless devices communicate with each other viathe PSE using a Time-Shared Full Duplex protocol and wherein the systemdoes not have a Parallel-configured Network Extender (PNE). The monocellwireless system can be powered by an alternate energy source such as,but is not limited to, a solar cell or a wind electrical power source toallow the system to operate in an autonomous mode. The monocell wirelesssystem may further comprise a Parallel Computing ArtificialIntelligence-based Call Routing system to monitor and analyzecommunication paths within and system and to allow the PSE to mimic thefunction of a PNE. External interface connections to an external networkcan be achieved wirelessly via a TSFD wireless ComDoc attached to theexternal network. The monocell system may include a method forcollecting revenue from each wireless set operating within the monocellsystem. Examples of methods for collecting revenue are disclosed in U.S.Pat. Nos. 6,141,531 and 6,842,617. In another embodiment, the monocellwireless system allows transmission in the CCAP or CCAP+ sub-protocolfrom one wireless device to another wireless device within the monocellsystem. In yet another embodiment, the monocell system can be controlledremotely by another wireless device outside the system via a satellite.In a further embodiment, the wireless devices in the monocell system canbe remotely controlled by another wireless device outside the system viaa satellite. Examples of methods to control the system or a wirelessdevice in the system are disclosed in U.S. Pat. Nos. 6,374,078 and6,842,617.

System Configurations

Turning now to FIG. 1, FIG. 1 shows a deployment 10 of two embodiments,11 (Parallel-Configured Wireless Communications System #1) and 12(Parallel-Configured Wireless Communications System #2), of a TSFDwireless communication system of the present invention connected toother communication networks 15, 16, 18, 19, and 1500. The TSFD wirelesscommunication system comprises fundamental elements that include TSFDwireless handsets 300, TSFD wireless external data communication modules(TSFD wireless X-DatComs) 400, TSFD wireless personal computer datacommunications cards (TSFD wireless PC-DatCom Cards) 500, TSFD wirelesscommunication docking bays (TSFD wireless ComDocs) 900,Parallel-configured TSFD Signal Extenders (PSEs) 600, andParallel-configured TSFD Network Extenders (PNEs) 800. Communicationbetween the various elements of the TSFD wireless communication systemutilizes the Time-Shared Full Duplex (TSFD) protocol disclosed in thepresent invention, and the communication is monitored by asystem-resident and fully decentralized Parallel Computing ArtificialIntelligence-based Distributive Routing System 1300.

The TSFD wireless handsets 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900 arecollectively herein referred to as the “TSFD wireless set” or the “TSFDwireless devices.” Unless otherwise stated, TSFD wireless handsets 300can be stand-alone handsets, or they can be associated with another TSFDwireless device.

Any fixed location wireless component that is permanently fixed to alocation is known as a “TSFD Anchored Component” and all wirelessdevices which are not fixed to a permanent location are herein known as“TSFD Mobile Devices.’ Thus, the “TSFD Anchored Components” include thePSEs 600 and the PNEs 800 while the “TSFD Mobile Devices” include theTSFD wireless handsets 300, TSFD wireless ComDocs 900, TSFD wirelessX-DatComs 400 and TSFD wireless PC-DatCom Cards 500. Although the TSFDwireless X-DatComs 400 are intended to be placed in a “fixed” locationand are not intended to be “mobile” in certain applications, theX-DatComs 400 are nevertheless considered as a “TSFD Mobile Device”since it is not fixed to a permanent location and can be moved easily ifneeded.

The TSFD wireless handsets 300 are similar in features and functions tocellular and PCS handsets. They can support one or more wirelesscommunications protocols: the primary TSFD Protocol described in thepresent disclosure, and one or more optional secondary protocol selectedfrom a multiple of wireless protocols (such as, but are not limited to,AMPS, D-AMPS, IS-95, IS-136, and GSM1900) and a PSTN 19 landlinecommunications protocol. The system infrastructure for the secondaryprotocol is not addressed in this disclosure but is well known to thoseskilled in the art. The wireless communication system infrastructure;PSEs 600 and PNEs 800, and the TSFD wireless protocol are completelyindependent of the secondary wireless protocols. In a preferredembodiment, there is no formal or actual connection between the PSE 600and the PSTN 19. The connection is accomplished by giving the PSE 600its own TSFD wireless ComDocs 900 waiting for the PSE 600 to utilizethem wirelessly.

As further illustrated in FIG. 1, the TSFD wireless X-DatCom 400 is acommunications device capable of utilizing one or more wirelesscommunications protocols, the primary TSFD Protocol and one or moreoptional secondary protocols selected from a multiple of wirelessprotocols (such as, but are not limited to, AMPS, D-AMPS, IS-95, IS-136,and GSM1900) and a PSTN 19 landline communications protocol. The TSFDwireless X-DatCom 400 is a remotely operated or preprogrammed wirelesscommunications device designed to be remotely placed to gather data,send or receive data, transfer data, and control such other devices asmay be attached to its circuitry externally. The device, in its simplestform, is a transmitter with related circuitry that gathers andwirelessly sends data on a predetermined schedule. In its mostcomplicated form, the TSFD wireless X-DatCom 400 is a remotely placed,remotely operated or preprogrammed autonomous TSFD wireless ComDoc-likedevice without handset recharging capabilities; capable of remotecontrol by wireless sets within the asynchronous wireless network or bythe Parallel Computing Artificial Intelligence-based DistributiveRouting System 1300, which is a resident computer network within theasynchronous wireless network. The TSFD wireless X-DatCom 400 can beoperated as an alternative communications path for a TSFD wirelessdevice to reach the PSTN 19 without accessing a signal path to the PSTN19 through the conventional PSE 600 to PNE 800 frequency links, and PNE800 to PSTN 19 interface. It can also be operated to serve as acommunications path from available and attached landline telephone sets,through the TSFD wireless X-DatCom 400 to a PSE 600 to a TSFD wirelessdevice. The TSFD wireless X-DatCom 400 can also be operated to serve asan alternative communications path for delivery of bi-directionalwireless wide-band Internet services to a selected computer via a PSE600 to PNE 800 to PSTN 19 interface signal path. The PSE 600 is a relaythat amplifies and translates the frequency of wireless radio frequency(RF) signals between TSFD wireless devices and a PNE 800, between twoTSFD wireless devices, between a TSFD wireless ComDoc 900 and PSE 600,and between a TSFD wireless handset 300 to PSE 600 to TSFD wirelessComDoc 900 to PSTN 19, between a TSFD wireless X-DatCom 400 and PSE 600,and between TSFD wireless handset 300 to PSE 600 to TSFD wirelessX-DatCom 400 to PSTN 19. The TSFD wireless X-DatCom 400 can also serveas an alternative communications path for delivering wireless signals toan external PCS network 1500 or for relaying signals from a computerthrough a TSFD wireless ComDoc 900 to a PSE 600 to the TSFD wirelessX-DatCom 400 to reach such an external network PCS 1500.

Further illustrating the embodiments of FIG. 1, the TSFD wireless ComDoc900 is a communications device capable of utilizing one or more wirelesscommunications protocols: the primary TSFD Protocol and one or moreoptional secondary protocols selected from a multiple of wirelessprotocols (such as, but are not limited to, AMPS, D-AMPS, IS-95, IS-136,and GSM1900) and a PSTN 19 landline communications protocol. The TSFDwireless ComDoc 900 can be operated to serve as an alternativecommunications path for TSFD wireless handsets 300 to reach the PSTN 19without accessing a signal path to the PSTN 19 through the conventionalPSE 600 to PNE 800 frequency links, and PNE 800 to PSTN 19 interface.The TSFD wireless ComDoc 900 can also be operated to serve as analternative communications path for the TSFD wireless X-DatCom 400 toreach the PSTN 19 without accessing a signal path to the PSTN 19 throughthe conventional PSE 600 to PNE 800 frequency links, and PNE 800 to PSTN19 interface.

As illustrated in FIG. 1, the TSFD wireless ComDoc 900 can also beoperated to serve as a communications path from the home or officelandline telephone sets, through the TSFD wireless ComDoc 900 to a PSE600 to a TSFD wireless handset 300. The TSFD wireless ComDoc 900 canalso serve as an alternative communications path for delivery ofbi-directional wireless wide-band Internet services to a home computervia a PSE 600 to PNE 800 to PSTN 19 interface signal path. The PSE 600is a relay that amplifies and translates the frequency of wireless radiofrequency (RF) signals between TSFD wireless handsets 300 and a PNE 800,between two TSFD wireless handsets 300, between a TSFD wireless ComDoc900 and PSE 600, and between TSFD wireless handset 300 to PSE 600 toTSFD wireless ComDoc 900 to PSTN 19, between a TSFD wireless X-DatCom400 and PSE 600, and between TSFD wireless handset 300 to PSE 600 toTSFD wireless X-DatCom 400 to PSTN 19. The TSFD wireless ComDoc 900 maybe used to route a TSFD wireless handset 300, via a Bluetooth interfaceto connect to the PCS network 1500 wirelessly.

There are many permutations and combinations of signal paths that arepossible in the present system. For example, TSFD wireless handsets 300,TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500, TSFDwireless TSFD wireless ComDocs 900 in the same microcell may communicatewith one another via a PSE 600. TSFD wireless handsets 300, TSFDwireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500, TSFD wirelessComDocs 900 in different microcells but within the same macrocell maycommunicate with on another via PSE 600 and PNE 800. Since computers andconventional telephones may be connected to a TSFD wireless X-DatCom400, these devices may also communicate with other devices connected tothe TSFD wireless network 11, 12 or to an external network such as 1500.Two or more computers may connect to one another via the TSFD wirelessnetwork, 11, 12 at a minimum data rate of 56 kbps using ContiguousChannel Acquisition Protocol, or up to a maximum data rate of 250 kbpsusing Contiguous Channel Acquisition Protocol Plus shown in FIG. 10, viaa single PSE 600. Similarly, since a laptop computer may be connected toa TSFD wireless handset 300, it may also communicate with other devicesconnected to the TSFD wireless network 11, 12 or an external network1500. Since a TSFD wireless X-DatCom 400 may also be connected to a PSTN19, cable or other communication network medium, a TSFD wireless handset300 may communicate directly or indirectly via a PSE 600 to a remotelyplaced TSFD wireless X-DatCom 400 to a PSTN 19 network or cable network.A TSFD wireless X-DatCom 400 may communicate via a PSE 600 and a PNE 800to a PSTN network 19 or may communicate via a PSE 600 and a PNE 800 to aPSTN network 19 to an external device 1400 for remote data gathering orextended remote control or the external device 1400.

In another embodiment of the invention, FIG. 1 further illustrates thatthe antenna pattern between the PSE 600 and TSFD wireless handsets 300,TSFD wireless DatCom 400, TSFD wireless ComDocs 900 is generallyomni-directional, since the TSFD wireless handsets 300 are typicallymobile throughout the surrounding area of the PSE 600 or the TSFDwireless DatCom 400 or TSFD wireless TSFD wireless ComDocs 900 may bemoved or placed in different locations at the discretion of thesubscriber. The antenna pattern of a TSFD wireless handset 300, a TSFDwireless ComDoc 900 or a TSFD wireless X-DatCom 400, operating in thesecondary mode, are also omni-directional. In contrast, the antennapattern between the PSE 600 and PNE 800 can be a narrow beam since thePSE 600 and PNE 800 sites are both at fixed locations. The PSE 600 isanalogous to a simplified “base transceiver station” or BTS in acellular or PCS system. A key point to simplification is that the PSE600 does not switch, process, or demodulate individual channels or callsunless otherwise instructed by the Parallel Computing ArtificialIntelligence Computer Network 1300 to make such connections during acatastrophic failure of the PNE 800. It is generally limited in functionto relaying blocks of RF spectrum. The PNE 800 is a central hub andprimary switch for interconnecting calls both within the system and toexternal networks such as the PSTN 19. The PNE 800 assists TSFD wirelesshandsets 300 in establishing calls, assists in interconnecting TSFDwireless ComDocs 900 and TSFD wireless handsets 300, TSFD wirelessX-DatCom 400 and TSFD wireless handsets 300, or TSFD wireless X-DatComs400 and TSFD wireless ComDocs 900 within the TSFD Protocol service area,assists TSFD wireless ComDoc 900 to TSFD wireless ComDoc 900 data linkswithin the TSFD Protocol service area, manages the voice/data andsignaling channels, and effectively connects calls for PSEs 600 that areconnected to the PNE 800. Since the PNE 800 must be in radioline-of-sight with the PSEs 600 that it services, its location site maybe critical in system deployment. An alternative fiber-optic PSE 600-PNE800 catastrophic failure network is also an option. A hardwareconnection between the PSE 600 and the PNE 800 may substitute fordifficult line-of-site deployments. The PNE 800 is analogous to asimplified “mobile switching center” or MSC in a cellular or PCS system.While an MSC may be compared to a telephone CO (central office) or TO(toll office) 18, the PNE 800 more closely compares to a PBX (PrivateBranch Exchange), which connects to a CO or TO 18. The PNE 800 enablesthe TSFD wireless communication systems 11, 12 to function independentlyof an external network; with the AI Network, serving as a catastrophicfailure backup Routing System 1300. Although FIG. 1 does not show aPC-DatCom Card, the antenna pattern between the PSE 600 and the otherwireless devices applies to the PC-DatCom Card as well.

FIG. 1 further provides illustration of the embodiments of TSFD wirelesscommunication systems 11, 12, deployed as networks. The networks 11, 12each consists of one or more fixed Anchored PNE sites and a number offixed PSE sites associated with each PNE 800. The networks 11, 12 areessentially the infrastructure required to service TSFD wirelesshandsets 300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards500 and TSFD wireless ComDocs 900 in a given geographical area. Anetwork that includes multiple PNEs 800 must support the exchange ofdigital voice, signaling, and data between the PNEs 800 in the network.The networks 11, 12 shown in FIG. 1, are isolated unless one or morePNEs 800 or PSEs 600 are connected to a PSTN 19, the Internet (forinternet services or voice-over-IP) 15 or to a dedicated fiber opticnetwork 16. With PSTN access, the networks 11, 12 can support callsbetween isolated networks 11, 12, as well as incoming and outgoing callswith other phones in the PSTN 19. Internet access via internet serviceproviders (ISPs) 15 enable remote system monitoring, data entry, sharingof system databases and voice-over IP, while connection to a dedicatedfiber optic cable 14 provides a dedicated fiber optic network 14 betweenPNE's 800, an alternate dedicated fiber optic network 14 signal routebetween PSEs 600 and PNEs 800, or an alternate dedicated fiber opticnetwork 14 signal route between PSE 600 and PSE 600. In a preferredembodiment, there is no formal or actual connection between the PSE 600and the PSTN 19. The connection can be accomplished by giving the PSE600 its own TSFD wireless ComDocs 900 waiting for the PSE 600 to utilizethem wirelessly.

Further illustrated in this alternate embodiment of the invention; FIG.1, the Parallel-Configured Wireless Communications System #1, 11,comprises three macrocells 22, where each macrocell includes a PNE 800communicating with a number of PSEs 600 that communicate with a numberof TSFD wireless handsets 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900. The PNEs 800and the PSEs 600 are connected together by communication backbones 13.PNEs 800 may also connect to a PSTN 19 via a telephone trunk line 17 toa central switching office (CO) 18. PNEs 800 may also connect to theInternet via a connection 14 to an Internet service provider (ISP) 15.PSEs 600 may also connect to a PSTN 19 via backup trunk lines to acentral switching office (CO) 18. PSEs 600 may also connect to theInternet via a connection 14 to an Internet service provider (ISP) 15.PSEs 600 may alternately connect to the PSTN 19 during a catastrophicfailure of the PNE 800 as suggested by the AI Network 1300 throughPSTN-PSE Interface 1600. In a preferred embodiment, there is no formalor actual connection between the PSE 600 and the PSTN 19. The connectionis accomplished by giving the PSE 600 its own TSFD wireless ComDocs 900waiting for the PSE 600 to utilize them wirelessly.

An additional embodiment of the invention, as illustrated in FIG. 1,TSFD wireless communication systems 11 and 12 may be interconnectedthrough the Internet 15, PSTN 19 connections, a TSFD wirelessComDoc-to-PSTN interface, TSFD wireless ComDoc-to-PSTN-Internetinterface, a TSFD wireless X-DatCom 400 to PSTN interface, a TSFDwireless X-DatCom 400 to PCS network 1500 interface, a TSFD wirelessX-DatCom 400 to TSFD wireless ComDoc 900 interface, a TSFD wirelesshandset 300 to TSFD wireless X-DatCom 400 interface, a PSTN 19 to TSFDwireless X-DatCom 400 interface, a TSFD wireless X-DatCom 400 to PSTN 19to External Device 1400 interface or a TSFD wireless X-DatCom 400 toPSTN 19 to Internet interface. Numerous other permutations of routingand connections are also possible but not shown specifically.

Turning now to FIG. 2, FIG. 2 shows an embodiment of a relationshipbetween adjacent macrocells 22 in a cellular topology 20. The fixed PNEand PSE sites of a TSFD wireless communication system are organized in acellular topology 20 similar to the tower arrangement in a cellular orPCS system. The cellular topology 20 promotes frequency reuse and iseffective in installation planning. In the present invention, two celltypes are defined: microcells 32 and macrocells 22 containing aplurality of microcells 32. The microcell 32 is the basic buildingblock, and the macrocell 22 is typically a group of 21 microcells 32 asshown in FIG. 2 in this embodiment.

Turning now to FIG. 3, FIG. 3 shows an embodiment of a relationshipbetween adjacent microcells 32 in a macrocell topology 30. A PSE 600 iscentral to each microcell 32, while a PNE 800 is central to eachmacrocell 22. Nine different microcell types are defined, designatedA1-3, B1-3, and C1-3, for the purpose of frequency division multipleaccess (FDMA). Each microcell type uses a common subset of frequencies.No two microcells 32 of the same type are ever adjacent, even whenmacrocells 32 are adjacent.

Turning now to FIG. 4, FIG. 4 shows the radio frequency spectrum 40 usedby the present TSFD wireless communication system. The present TSFDwireless communication system utilizes the Broadband radio frequencyspectrum of from 50 megahertz to 5 gigahertz. The spectrum is dividedinto low band and high band separated by a separating spectrum of 10 to80 megahertz, wherein the low band and the high band have an equalamount of the spectrum. In a preferred embodiment, the spectrum is thePCS spectrum licensed in the United States by the Federal CommunicationsCommission (FCC). The frequency range that it covers is between 1850megahertz and 1990 megahertz, and includes PCS low band 42 and PCS highband 44. Licenses must be acquired for one or more PCS blocks, A throughF, shown in FIG. 4.

Turning now to FIG. 5, FIG. 5 provides that the TSFD radio frequencyprotocol 50 used by an embodiment of the present TSFD wirelesscommunication system. The TSFD protocol 50 utilizes the PCS spectrum asillustrated in FIG. 5. The PCS low band 42 is reserved for PSE 600receive frequencies, and the high band 44 for PSE 600 transmitfrequencies. Half of each band is reserved for signals between the PSEs600 and a TSFD wireless device with the other half for signals betweenthe PSEs 600 and the PNE 800. Regarding the TSFD wireless communicationssystem depicted in FIG. 5, a TSFD wireless ComDoc 900 communicates witha PSE 600 in the same manner that any TSFD wireless device. With duplexfiltering and 80-MHz separation between the low band 42 and high band44, the PSE 600 can simultaneously receive and transmit signals withoutcompromising receiver sensitivity. This frequency plan allows calls totake place asynchronously, which simplifies the design. Although manypossible timing architectures may be used in the present TSFD wirelesscommunication system, an asynchronous system architecture is selected toprovide the best fit to the key requirements of cost, range, userdensity and human limitations to perceptibility of delayed audio signalswithin the TSFD Protocol network. Asynchronous operation of the presentTSFD wireless communication system allows greater flexibility in systemgeographic layout, simpler digital protocol, and channel separationstructure. Conventional digital cellular and PCS systems are designedsuch that synchronous operation is a necessity. CDMA cellular/PCSsystems require synchronous operation to insure demodulation and precisecoordination of power control and TDMA cellular/PCS systems requiresynchronous operation to prevent time slot interference. Synchronousoperation allows the system design to make very efficient use of theassigned spectrum (high user density) for a given size geographic areafor a trade-offs in system complexity, cost, flexibility and limits onrelaying signals within a cell site's control. The present TSFD wirelesscommunication system has lower density requirements (rural environment),so the advantages of asynchronous operation became very beneficial tothe required cost effectiveness of the present system design. Humanphysiology is unable to detect delays in an audio signal of up to 80milliseconds. Advantages of this asynchronous operation becomes verybeneficial when sending signals from PSE 600 to PSE 600 over greatdistances that approach this 80 millisecond human threshold of detectability. Estimates by wireless engineers are in excess of 1,000 milesfor the relaying of voice signals within this asynchronous system beforethe user becomes aware of a delay in the audio. No synchronous PCSsystem can even approach distances as great as 27 miles whenrelaying/repeating audio signals within a given cell tower's control;restricted by the speed of light and the absolute requirement to staysynchronized with the tower from which the audio signal derived and inwhich the handset is registered operationally. FIG. 5 also shows how thePCS bands are further divided into sub-bands dedicated for each of the 9microcell types. Each microcell shown in FIG. 3 uses the sub-bandsassigned for its particular type (alpha-numeric designator A1, A2, A3,B1, B2, B3, C1, C2, or C3) in order to preclude interference withadjacent microcells (since adjacent microcells are never of the sametype). The microcell sub-bands are 825 kHz wide for PCS blocks ABC, and275 kHz wide for blocks DEF. The definition of 9 microcell typesprovides two additional non-adjacent types beyond the minimum 7 that arerequired for a hexagonal cell layout with FDMA shown in FIG. 3. For amicrocell 32 in the cell pattern illustrated in FIG. 3, the additionaltwo non-adjacent types are the other two alpha designators with the samenumeric designator. For example, the sub-bands for microcell types A2and C2 are not used in the microcells adjacent to microcell B2.Sub-bands A1ML, A2ML, A3ML, B1ML, B2ML, B3ML, C1ML, C2ML and C3ML areassigned to communication from a TSFD wireless handset 300, a TSFDwireless ComDoc 900 or a TSFD wireless X-DatCom 400 to a PSE 600.Sub-bands A1MH, A2MH, A3MH, B1MH, B2MH, B3MH, C1MH, C2MH and C3MH areassigned to communication from a PSE 600 to a TSFD wireless handset 300,a TSFD wireless ComDoc 900 or a TSFD wireless X-DatCom 400. Sub-bandsA1XL, A2XL, A3XL, B1XL, B2XL, B3XL, C1XL, C2XL and C3XL are assigned tocommunication from a PNE 800 to a PSE 600. Sub-bands A1XH, A2XH, A3XH,B1XH, B2XH, B3XH, C1XH, C2XH and C3XH are assigned to communication froma PSE 600 to a PNE 800. Although FIG. 5 does now show a TSFD wirelessPC-DatCom Card, the TSFD radio frequency protocol 50 used as describedabove can be applied to the TSFD wireless PC-DatCom Card.

Turning now to FIG. 6, FIG. 6 illuminates examples of signal flow indiagram 60 of communication paths 61, 62, 63, 64, 65, 66, 67, 68, 61 a,64 a, 65 a, 68 a, 15 x, 1400 x and 19 x. These paths illustrate signalflow between a TSFD wireless handset 302, a TSFD wireless ComDoc 901,located in two different microcells B1, 73 and B2, 75, respectively.These paths also illustrate a path of signal flow between a TSFDwireless handset 301 and a TSFD wireless X-DatCom 400; furtherconnecting to a remote device 1400 via a dedicated connection 1400 x;with TSFD wireless handset 301 and TSFD wireless X-DatCom 400 located intwo different microcells B1, 73 and B2, 75, respectively. These pathsfurther illustrate a path of signal flow between a TSFD wireless handset301, a PSE 601, a PNE 801, a PSE 602, a remotely placed TSFD wirelessX-DatCom 400, the PSTN 19, on to some designated landline number; withTSFD wireless handset 301 and TSFD wireless X-DatCom 400 located in twodifferent microcells B1, 73 and B2, 75, respectively. Diagram 60provides illustration of additional paths of signal flow between a TSFDwireless X-DatCom 400, a PSE 600, a PNE 800 and an Internet ISP 15. Italso shows an example of a signal flow between TSFD wireless handset301, a PSE 601, a TSFD wireless ComDoc 901, located in the samemicrocell B1; interconnecting to an ISP 15, externally via a Cable 15 x.Additional paths are further illustrated through the signal flow betweena TSFD wireless handset 302, a PSE 602, a TSFD wireless X-DatCom 400 andthe PSTN 19; indicative of a path chosen to signal a TSFD wirelessX-DatCom 400, via the TSFD wireless handset 302, to download datacollected by the TSFD wireless X-DatCom 400, to a remote locationattached to the PSTN 19 which is not shown.

Further illustrative of an embodiment of the present invention, FIG. 6describes an extended path call is shown between the TSFD wirelesshandset 302 and the TSFD wireless ComDoc 901 in two different microcells73, 75 that are switched at a PNE 801 in a macrocell A2, 74. Thecommunication from the TSFD wireless handset 302 to the PSE 602 inmicrocell B2, 75 is omni-directional and is carried on sub-band B2ML 64a. The communication from the PSE 602 to the TSFD wireless handset 302in microcell B2, 75 is omni-directional and is carried on sub-band B2MH65 a. The communication from the PSE 602 in microcell B2, 75 to the PNE801 in macrocell A2, 74 is highly directional and is carried on sub-bandB2XH 66. The communication from the PNE 801 in macrocell A2, 74 to thePSE 602 in microcell B2, 75 is highly directional and is carried onsub-band B2XL 63. The communication from the PNE 801 in macrocell A2, 74to the PSE 601 in microcell B1, 73 is highly directional and is carriedon sub-band B1XL 67. The communication from the PSE 601 in microcell B1,73 to the PNE 801 in macrocell A2, 74 is highly directional and iscarried on sub-band B1XH 62. The communication from the PSE 601 inmicrocell B1, 73 to the TSFD wireless ComDoc 901 in microcell B1, 73 isomni-directional and is carried on sub-band B1MH 68 a. The communicationfrom the TSFD wireless ComDoc 901 in microcell B1, 73 to the PSE 601 inmicrocell B1, 73 is omni-directional and is carried on sub-band B1ML 61a.

A second extended path call is shown; in FIG. 6, between the TSFDwireless handset 301 and a TSFD wireless X-DatCom 400 in two differentmicrocells 73, 75 that are switched at a PNE 801 in a macrocell A2, 74.The communication from the TSFD wireless handset 301 to the PSE 601 inmicrocell B1, 73 is omni-directional and is carried on sub-band B1ML 61.The communication from the PSE 601 to the TSFD wireless handset 301 inmicrocell B1, 73 is omni-directional and is carried on sub-band B1MH 68.The communication from the PSE 601 in microcell B1, 73 to the PNE 801 inmacrocell A2, 74 is highly directional and is carried on sub-band B1XH62. The communication from the PNE 801 in macrocell A2, 74 to the PSE601 in microcell B1, 73 is highly directional and is carried on sub-bandB1XL 67. The communication from the PNE 801 in macrocell A2, 74 to thePSE 602 in microcell B2, 75 is highly directional and is carried onsub-band B2XL 63. The communication from the PSE 602 in microcell B2, 75to the PNE 801 in macrocell A2, 74 is highly directional and is carriedon sub-band B2XH 66. The communication from the PSE 602 in microcell B2,75 to the TSFD wireless X-DatCom 400 in microcell B2, 75 isomni-directional and is carried on sub-band B2MH 65. The communicationfrom the TSFD wireless X-DatCom 400 in microcell B2, 75 to the PSE 602in microcell B2, 75 is omni-directional and is carried on sub-band B2ML64. The path to and from the remote device 1400, is hardwired to theTSFD wireless X-DatCom 400. An alternate path at the TSFD wirelessX-DatCom 400 may route the signal from the remote device 1400,subsequently to an external PSTN landline telephone located outside thisdiagram. The active signal to make such a signal divert within the TSFDwireless X-DatCom 400 from one destination to another may be sent by theorigination TSFD wireless handset 301 via the same path previouslydesignated between the TSFD wireless handset 301 and the TSFD wirelessX-DatCom 400; via a proprietary control code.

A third extended path call is shown; in FIG. 6, between a TSFD wirelessX-DatCom 400 and an Internet ISP 15 in two different microcells 73, 75that are switched at a PNE 801 in a macrocell A2, 74. The communicationfrom the TSFD wireless X-DatCom 400 to the PSE 602 in microcell B2, 75is omni-directional and is carried on sub-band B2ML 64. Thecommunication from the PSE 602 to the X-DatCom 400 in microcell B2, 75is omni-directional and is carried on sub-band B2MH 65. Thecommunication from the PSE 602 in microcell B2, 75 to the PNE 801 inmacrocell A2, 74 is highly directional and is carried on sub-band B2XH66. The communication from the PNE 801 in macrocell A2, 74 to the PSE602 in microcell B2, 75 is highly directional and is carried on sub-bandB2XL 63. The communication from the PNE 801 in macrocell A2, 74 to thePSE 601 in microcell B1, 73 is highly directional and is carried onsub-band B1XL 67. The communication from the PSE 601 in microcell B1, 73to the PNE 801 in macrocell A2, 74 is highly directional and is carriedon sub-band B1XH 62. The communication from the PSE 601 in microcell B1,73 to the TSFD wireless ComDoc 901 in microcell B1, 73 isomni-directional and is carried on sub-band B1MH 68 a. The communicationfrom the TSFD wireless ComDoc 901 in microcell B1, 73 to the PSE 601 inmicrocell B1, 73 is omni-directional and is carried on sub-band B1ML 61a. The path to and from the ISP 15, from the TSFD wireless ComDoc 901,is achieved via a cable provided by the ISP service provider.

An alternate embodiment of the present invention provides, also in FIG.6, a local path call is shown between the TSFD wireless handset 301, aPSE 601 and the TSFD wireless ComDoc 901 in the same microcell 73. Thecommunication from the TSFD wireless handset 301 to the PSE 601 inmicrocell B1, 73 is omni-directional and is carried on sub-band B1ML 61.The communication from the PSE 601 to the handset 301 in microcell B1,73 is omni-directional and is carried on sub-band B1MH 68. Thecommunication from the PSE 601 in microcell B1, 73 to the TSFD wirelessComDoc 901 in microcell B1, 73 is omni-directional and is carried onsub-band B1MH 68 a. The communication from the TSFD wireless ComDoc 901in microcell B1, 73 to the PSE 601 in microcell B1, 73 isomni-directional and is carried on sub-band B1ML 61 a.

An additional a local path call is shown; in FIG. 6, between the TSFDwireless handset 302, a PSE 602, the TSFD wireless X-DatCom 400 and aninterface with the PSTN 19 in the same microcell 75. The communicationfrom the TSFD wireless handset 302 to the PSE 602 in microcell B2, 75 isomni-directional and is carried on sub-band B2ML 64 a. The communicationfrom the PSE 602 to the TSFD wireless handset 302 in microcell B2, 75 isomni-directional and is carried on sub-band B2MH 65 a. The communicationfrom the PSE 602 in microcell B2, 75 to the X TSFD wireless -DatCom 400in microcell B2, 75 is omni-directional and is carried on sub-band B2MH65. The communication from the TSFD wireless X-DatCom 400 in microcellB2, 75 to the PSE 602 in microcell B2, 75 is omni-directional and iscarried on sub-band B2ML 64. The path from the TSFD wireless X-DatCom400 to the PSTN 19 is via a standard telephone line plugged into theTSFD wireless X-DatCom 400.

Turning now to FIG. 7, FIG. 7 shows a signal flow diagram 70 ofcommunication paths 76, 77, 77 a, 77 b, 77 c, 77 d, and 77 e between aTSFD wireless X-DatCom 400, a computer 909, a Laptop Computer (with aTSFD wireless PC-DatCom Card 500 activated) 303, a PSE 603, a TSFDwireless ComDoc 903, alternately a route to a TSFD wireless handset 907,alternately a route to the PSTN 905, alternately a route to a computer909, further on from the computer 909 to a TSFD wireless X-DatCom 400,further on from the TSFD wireless X-DatCom 400 to a remote device 1401;within the same microcell C3, 71. The signal flow diagram 60 illustratesan example of frequency usage in the system. In FIG. 7, a local pathcall is shown between the Laptop 303 and the TSFD wireless ComDoc 903 inthe same microcell C3, 71, in which case no central PNE switching isrequired. Note in FIG. 7 that the sub-band used for the local path callsdiffers from the microcell type, but is usable because it is one of thetwo non-adjacent microcell types (i.e., different alpha, but samenumeric designator). The communication path from the Laptop 303 (withthe TSFD wireless PC-DatCom Card 500) to the PSE 603 is carried onsub-band B3ML 76, and the communication from the PSE 603 to the TSFDwireless ComDoc 903 is carried on sub-band B3MH 77. The communicationpath from the TSFD wireless ComDoc 903 to the PSE 603 is carried onsub-band B3ML 76, and the communication from the PSE 603 to the TSFDwireless ComDoc 903 is carried on sub-band B3MH 77. General control andoperational state control have also been achieved over TSFD wirelessX-DatCom 400 by this network link via the computer 909. The connectionbetween TSFD wireless ComDoc 903 and computer 909 is achieved via astandard computer data cable.

In another embodiment of the present invention, FIGS. 6 and 7 depict thephysical relationships between TSFD wireless handset 301 and 907, TSFDwireless ComDocs 900, 901, 903, PSEs 600, 601-603, PNE 801, TSFDwireless X-DatCom 400, remote devices 1400 and 1401 computers 303 and909; microcells 71, 73, 74, and 75 and a macrocell. A macrocell is ableto utilize the full amount of PCS spectrum that is licensed. This isachieved by including at least one microcell of each of the 9 types(A1-3, B1-3, C1-3) in a macrocell, as shown in FIG. 3. In addition,spectrum may be reused within a macrocell among non-adjacent microcellsand through the use of directional antennas for the PSE 600-to-PNE 800communication links, which are between fixed sites. Spectrum may also bepreserved by utilizing direct fiber optic connections between individualPSEs 600 and between PSEs 600 and PNEs 800. When all connections betweenPSEs 600 and PNEs 800 are by direct fiber optic connection, the spectrumreserved for PSE 600 to PNE 800 communication can be utilized bywireless devices communicating exclusively with PSEs 600. The radiofrequency (RF) waveform within the TSFD protocol system is producedusing GMSK (Gaussian Minimum Shift Keying) modulation and a data rate of16 kbps. Baseband filtering limits the 3-dB channel bandwidth to 12.5kHz. The resultant waveform is a “constant envelope” type, meaning thatthere is no intended amplitude modulation. The TSFD wirelesscommunication system RF coverage and range depend upon the RF parametersof the system (frequency, bandwidth, transmit power, receivesensitivity, antenna gain, etc.), the radio horizon, and the amount ofsignal occlusion in the line-of-sight between the PSE 600 and TSFDwireless handset 300 or other such wireless devices found within theTSFD Protocol system. The RF parameters are specified so that the radiohorizon is normally the limiting factor. The radio horizon is a functionof the antenna heights and curvature of the earth. As an example, an PSEantenna on top of a 100-foot tower can “see” TSFD wireless handsets 300,or other such wireless devices, located out to about 14 miles actualground distance from the base of the tower. Terrain and man-madestructures present the potential for signal occlusions, i.e.,non-line-of-sight conditions, which reduce effective coverage and range.Urban propagation models for RF signals show a significant decrease inrange compared to clear line-of-sight conditions. For example, the RFconditions that yield 253 miles of range when operated with a clearline-of-sight yield only 4 miles with the urban model. For systems otherthan the PCS bands, higher or lower frequencies in the magnetic spectrumyield significantly different characteristics, such as when utilized forTSFD Protocol transmissions, which is frequency independent. Thedeployment of the TSFD wireless communication system in rural areasalleviates the potential for urban occlusions, but terrain is still afactor. Microcell/macrocell layout and PSE/PNE antenna site selectionwill be required for each installation based on careful planning,consideration, and test of the propagation conditions and physicalconstraints of the geographical area. The use of the 1.9-GHz PCSspectrum affects the range, amount of multi-path, and signal penetrationcapability compared to other frequency bands such as VHF and UHF, andtherefore must be considered in site layout and planning.

As further illumination of the present invention, TSFD channelizationprotocol includes elements of control (signaling) and data (voice/data).The available RF spectrum; FIG. 4 and FIG. 5, is broken down intovoice/data and signaling channels as shown in the table presented inFIG. 28, which shows the number of channels per microcell per PCS block.The total number of extended plus local channels may not be availablefor simultaneous use. A minimum total of 96 channels are required.Channels are comprised of a transmit/receive pair of frequenciesseparated by 80 MHz. The TSFD wireless handset uplink (handset to PNE)uses two channel halves, one for TSFD wireless handset 300 to PSE 600,and one for PSE 600 to PNE 800. Similarly, the TSFD wireless handsetdownlink (PNE to handset) uses the other halves of the same twochannels, one for PNE 800 to PSE 600, and one for PSE 600 to TSFDwireless handset 300. The PSE 600 provides the necessary frequencytranslation for both the uplink and downlink. The TSFD wireless handsetand PNE channel pairs are different, but 80 MHz separates each pair. Thefixed 80-MHz offset is built into the TSFD wireless handset and PNEtransceiver designs to allow for microsecond switching between receiveand transmit functions. Local path calls, as shown in FIG. 7, present anexception to the channel concept described in the preceding discussionbecause these calls do not have an uplink/downlink with the PNE 800. Asa result, they use only one channel pair, which is shared between thetwo TSFD wireless handsets 300. The PSE 600 is still required to providethe frequency translation.

Turning now to FIG. 8—diagram 80, shows voice or data frames and packetsbetween two TSFD wireless devices. In FIG. 8, a TSFD wireless handsetand a TSFD wireless TSFD wireless ComDoc are shown for illustrativepurposes. The TSFD wireless handset or the TSFD wireless ComDoc mayactually, in practice, be any TSFD wireless device. A number of voicedata channels (VDCs) are used in each microcell to carry voice/data calltraffic in the TSFD wireless communication system. Each VDC is dedicatedto a single call (i.e., voice/data channels are not multiplexed) tosimplify the design. Two VDC types are defined, extended path and localpath, as illustrated in FIGS. 6 and 7. Four fixed physical frequenciesfrom the microcell sub-band spectrum are allocated for each extended VDC(i.e., uplink from TSFD wireless handsets 300 to PSE 600, uplink fromPSE 600 to PNE 800, downlink from PNE 800 to PSE 600, and downlink fromPSE 600 to TSFD wireless handsets 300). In contrast, the frequencies forthe local VDCs are allocated from the sub-band spectrum of one of thetwo non-adjacent microcell types, which are identified by differentalpha, but same numeric designator. For example, in microcell type B2,the local VDCs use the frequencies from microcell type A2 or C2. Sincethese cells are non-adjacent, interference is precluded. It is notedthat for the local VDC, only two fixed physical frequencies are required(i.e., uplink from TSFD wireless handsets 300 to PSE 600, downlink fromPSE 600 to TSFD wireless handsets 300) since the PNE 800 is notutilized. Local VDCs are contained within the microcell, while extendedVDCs are connected through the PNE 800 to other microcells, macrocells,and/or the PSTN 19. Calls between TSFD wireless handsets 300 located inthe same microcell use local VDCs to increase system capacity byreducing the number of calls switched through the PNE 800. The use ofseparate sub-band blocks for extended and local path/data channelsallows the PSE 600 to relay the extended VDCs to the PNE 800, and thelocal VDCs back within the microcell for receipt by other TSFD wirelesshandsets 300. The number of VDCs in a microcell depends on the amount ofspectrum that is available: 38 VDCs (19 local, 19 extended) asillustrated and defined in FIG. 26, in a 5-MHz block (D, E, or F) or 96VDCs (63 max local, 63 max extended) also illustrated and defined inFIG. 26, in a 15-MHz block (A, B, or C). One VDC is required for eachcall in a microcell. Extended VDCs support one TSFD wireless handset orTSFD wireless ComDoc. Local VDCs support two TSFD wireless handsets 300,or a TSFD wireless handset and a TSFD wireless ComDoc, but still onlyone call. The advantage of the local VDC is that the TSFD wirelesshandsets 300 share the channel (which saves a VDC), and thecomplementary channels for the uplink/downlink are not required (whichsaves two more VDCs). The result is one channel pair required versusfour channel pairs for an extended path call. Whenever one of the TSFDwireless handsets 300 on a local VDC call leaves the microcell, the callmust be handed off to separate extended VDCs for each TSFD wirelesshandset. The VDC protocol is half-duplex on the physical channel, but iseffectively full duplex from the user's perspective. This is achieved bybuffering and encoding the digitized voice data, and transmitting it inpackets at a higher data rate than is required for real-time decoding.As a result, the TSFD wireless handset is able to toggle back and forthbetween its transmit and receive functions at an even rate (50%transmit, 50% receive). This alternating transmit-receive “ping-pong”approach is illustrated in FIG. 8. An advantage of the ping-pongapproach is that full-duplex transmit and receive functionality is notrequired of the TSFD wireless handset. Consequently the TSFD wirelesshandset architecture uses a transmit/receive (TR) switch instead of aduplexer, to significantly reduce cost, size, and weight. A 40 ms voiceframe (20 ms transmit window, 20 ms receive window) will be utilized asshown in FIG. 8 based on the vocoder (voice encoder/decoder) packetsize. The frame length sets the minimum buffering delay since the voicesignal must be fully acquired in real-time and packetized beforetransmission. Delays due to frame lengths much above 40 ms may becomeperceptible to the user. On the other hand, short frame lengths muchless than 40 ms reduce efficiency and are not desired. Some callmaintenance actions require that the TSFD wireless handset drop a voiceframe. This may be perceptible to the user but will be an infrequentoccurrence. This approach allows the TSFD wireless handset to use onlyone transmitter to conserve size, weight, power consumption, and cost. Asmall amount of in-band signaling data is available on the VDC, forexample, DTMF (dual-tone multi-frequency) codes for digits dialed duringa call, and call progress codes including hang up indication. Thisin-band signaling data is shown on FIG. 8, labeled “OH” for overheaddata. As shown in FIG. 8, 40 ms encoded voice frames 81 are compressedinto a transmit window voice packet 82 and transmitted from the handsetwith overhead data OH. The voice and overhead packets are received as areceived window voice packets 83 by the TSFD wireless TSFD wirelessComDoc and decompressed into 40 ms decoded voice frames 84. The reverseof this process is being carried on by the TSFD wireless TSFD wirelessComDoc compressing and transmitting to the handset where the voice frameis decompressed and decoded by the handset.

Turning now to FIG. 9 shows four channel Contiguous Channel AcquisitionProtocol (CCAP) data frames and packets transmitting and receivingbetween any two TSFD wireless devices, as illustrated by a TSFD wirelesshandset and a TSFD wireless ComDoc in the figure. As shown in FIG.9—diagram 90, 40 ms encoded voice frames 91 are compressed into atransmit window data packet 92, which comprises four contiguous voicechannels, and transmitted from the TSFD wireless ComDoc with overheaddata OH. The data and overhead packets are received as a received windowdata packets 93 by the TSFD wireless handset and decompressed into 40 msdecoded data frames TSFD wireless handset compressing and transmittingto the TSFD wireless ComDoc where the data frame is decompressed anddecoded by the TSFD wireless handset. By using four contiguous voicechannels to transmit data, the channel bandwidth is increased four-fold,or up to approximately 56 kbps. This feature enables a laptop computerconnected to a TSFD wireless handset to communicate at a 56 kbps ratewith a second computer connected to another TSFD wireless handset. Othercommunication paths are also possible, as in FIG. 7 where a laptop couldbe connected to a TSFD wireless handset communicating via a TSFDwireless ComDoc and a PSTN to an Internet service provider. If twelvecontiguous voice channels were available to transmit data using a CCAP+protocol, the channel bandwidth may be increased twelve-fold asilluminated in FIG. 10, or up to approximately 250 kbps. The addedbandwidths are obtained by adding adjacent channels together to obtain ahigher data rate. A third type of VDC, the distant VDC, is not shown inFIG. 8, but is similar to the extended VDC except that the communicationpath is between a distant TSFD wireless device and a remotely placeddistant TSFD wireless device in a different microcell and in a differentmacrocell.

Turning now to FIG. 10 shows 12 channel Contiguous Channel AcquisitionProtocol (CCAP+) data frames and packets transmitting and receivingbetween any two TSFD wireless devices, as illustrated by a TSFD wirelesshandset and a TSFD wireless TSFD wireless ComDoc in the figure. As shownin FIG. 10—diagram 1000, 40 ms encoded voice frames are compressed intoa transmit window data packet 1092, which comprises twelve contiguousvoice channels, and transmitted from the handset with overhead data OH.The data and overhead packets are received as a received window datapackets 1093 by the TSFD wireless ComDoc and decompressed into 40 msdecoded data frames TSFD wireless handset compressing and transmittingto the TSFD wireless ComDoc set where the data frame is decompressed anddecoded by the TSFD wireless handset. By using twelve contiguous voicechannels to transmit data, the channel bandwidth is increased four-fold,or up to approximately 250 kbps. This feature enables a laptop computerconnected to a TSFD wireless handset to communicate at a 250 kbps. Othercommunication paths are also possible, as in FIG. 7 where such a laptopis connected to a TSFD wireless handset communicating via a TSFDwireless ComDoc and a PSTN to an Internet service provider. When twelvecontiguous voice channels are available to transmit data using a CCAP+protocol, the channel bandwidth may be increased twelve-fold asilluminated in FIG. 10, or up to approximately 250 kbps. The additionalbandwidths may be obtained by adding adjacent channels together toobtain an even higher data rate.

Turning now to FIG. 11 shows 12 channel Contiguous Channel AcquisitionProtocol (CCAP+) data frames and packets transmitting and receivingbetween two TSFD wireless devices, as illustrated by a TSFD wirelesshandset and a TSFD wireless TSFD wireless ComDoc in the figure. As shownin FIG. 10—diagram 1000, 40 ms encoded voice frames are compressed intoa transmit window data packet 1092, which comprises twelve contiguousvoice channels, and transmitted from the handset with overhead data OH.The data and overhead packets are received as a received window datapackets 1093 by the TSFD wireless ComDoc and decompressed into 40 msdecoded data frames TSFD wireless handset compressing and transmittingto the TSFD wireless ComDoc set where the data frame is decompressed anddecoded by the TSFD wireless handset. By using twelve contiguous voicechannels to transmit data, the channel bandwidth is increased four-fold,or up to approximately 250 kbps. This feature enables a laptop computerconnected to a TSFD wireless handset to communicate at a 250 kbps.

Within the standard Time-Shared Full Duplex Protocol diagram aninsertion is made of digital data in a continuous flow. This transitionfrom TSFD to the Integrated Direct Data Transfer or IDDT sub-protocolrequires that each wireless device formerly in the “Send-Receive” modecease bi-directional broadcasts in favor of only one of the TSFDwireless devices sending and the other receiving. This condition cannotbe activated independently of the TSFD Protocol; but is an integratedpart of the protocol used exclusively to transfer digital data; i.e.,live video streaming (packetized as in Internet transfers) Following thecompletion of the “feed” the system automatically returns to theprevious mode of “Send-Receive” signaling. Setup and Teardown commandsare part of the software driving the TSFD Protocol and as such isapplicable to all TSFD wireless Anchored Components and TSFD MobileDevices as defined and embodied within this disclosure.

Other communication paths are also possible, as in FIG. 7 where such alaptop is connected to a TSFD wireless handset 907 communicating via aTSFD wireless ComDoc 903 and a PSTN 905 to an Internet service provider.When twelve contiguous voice channels are available to transmit datausing a CCAP+ protocol, the channel bandwidth may be increasedtwelve-fold as illuminated in FIG. 10, or up to approximately 250 kbps.The additional bandwidths may be obtained by adding adjacent channelstogether to obtain an even higher data rate.

Turning now to FIG. 12, FIG. 12—diagram 100, shows reference channelframing. A single, shared Reference Channel (RC) is used in eachmicrocell for broadcast to TSFD wireless handsets 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD wirelessComDocs 900. Four fixed physical frequencies from the microcell sub-bandspectrum are allocated for the RC (i.e., uplink from TSFD wirelesshandsets 300, TSFD wireless ComDocs 900, X-DatComs 400 or TSFD wirelessPC-DatCom 500 to PSE 600, uplink from PSE 600 to PNE 800, downlink fromPNE 800 to PSE 600, and downlink from PSE 600 to TSFD wireless handsets300), although the TSFD wireless handset 300, TSFD wireless ComDoc 900,TSFD wireless X-DatCom 400 and TSFD wireless PC-DatCom 500 uplink is notutilized. The TSFD wireless handsets 300, TSFD wireless X-DatComs 400,TSFD wireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900 read theRC to identify the presence of service. Without the RC, the TSFDwireless handsets 300, TSFD wireless X-DatComs 400, TSFD wirelessPC-DatCom Cards 500 and TSFD wireless ComDocs 900 are inoperable.Besides identifying wireless communication system service, the RC isused by the TSFD wireless handsets 300, TSFD wireless X-DatComs 400,TSFD wireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900 toadjust its internal frequency reference (typically a voltage-controlledtemperature-compensated crystal oscillator or VCTCXO). This adjustmentcapability allows the TSFD wireless handsets 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD wirelessComDocs 900 to achieve increased frequency accuracy and stability andthus improved bit-error performance in demodulation of signals. Thefollowing information is also provided to the TSFD wireless handset onthe RC:

Date and Time

Microcell/Macrocell Identification Code

TSFD Wireless Mobile Device Attention Codes (supports the CMC, describedbelow)

Broadcast Text Messages

The PNE 800 also transmits special commands on the RC downlink that areaddressed to the PSE 600 rather than the TSFD wireless handsets 300,TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFDwireless ComDocs 900. These commands are used to remotely enable/disablethe PSE 600 and assign the microcell type (which sets the frequencysub-blocks for use). Remote control of the microcell type providessystem frequency agility. The RC uplink, while not used by the TSFDwireless handsets 300, TSFD wireless X-DatComs 400, TSFD wirelessPC-DatCom Cards 500 and TSFD wireless ComDocs 900, is used by the PSE600 for command acknowledgement and status reporting to the PNE 800.There are 9 unique RC frequencies in the TSFD wireless communicationsystem, one for each microcell type. TSFD wireless handsets 300, TSFDwireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFDwireless ComDocs 900 continually scan the RCs in order to identify theTSFD wireless handsets 300, TSFD wireless X-DatComs 400, TSFD wirelessPC-DatCom Cards 500 and TSFD wireless ComDocs 900 microcell/macrocelllocation. This is accomplished by monitoring the RC power levels andreading the microcell/macrocell ID codes. Real-time tracking of TSFDwireless handsets 300, TSFD wireless X-DatComs 400, TSFD wirelessPC-DatCom Cards 500 and TSFD wireless ComDocs 900 microcell location isimportant for mobile wireless communication because TSFD wirelesshandsets 300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards500 and TSFD wireless ComDocs 900 are required when TSFD wirelesshandsets 300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards500 and TSFD wireless ComDocs 900 can move between microcells. In orderto facilitate RC scanning while a call is active, the TSFD wirelesshandsets 300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards500 and TSFD wireless ComDocs 900 architecture includes two parallelreceivers; one dedicated to the VDC, and the other dedicated to RCscanning. As shown in FIG. 8, the handset/TSFD wireless ComDoc receivefunction is limited to about 50% duty factor when on a call. The lengthof the handset/TSFD wireless ComDoc receive window is 20 ms based on thevocoder packet size. At the system 16 kbps data rate, 20 ms amounts to320 bits. In order for the TSFD wireless handsets 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD wirelessComDocs 900 to ensure receipt of a complete RC message, the messagelength must be less than ½ of the handset/TSFD wireless ComDoc receivewindow, or 10 ms, which amounts to 160 bits. In this case, for designpurposes, the RC frame is limited to 150 bits. In order to meet thissize limitation, data may be distributed across multiple framesresulting in a super frame. For example, broadcast messages aredistributed across a super frame with only a few bytes in each frame.Each RC frame within the super frame is repeated four consecutive timesbefore advancing to the next frame; this is referred to as a block. Eachblock should be the same length as the 40 ms transmit/receive voiceframe. Repeating the RC frame transmission four times ensures that acomplete 10-ms RC frame will fall within the 20-ms handset/TSFD wirelessComDoc receive window no matter where the receive window begins withinthe 40-ms block. This process is illustrated in FIG. 9, which shows anexample of TSFD Protocol wireless voice frame alignment with RC frames.

Turning now to FIG. 13, FIG. 13 shows the signal flows for a callinitiation channel (CIC) 101, 103, 105, 107 and a call maintenancechannel (CMC) 102, 104, 106, 108. A single, shared CIC 101, 103, 105,107 is used in each microcell for TSFD wireless ComDoc 900 registrationand call establishment. Four fixed physical frequencies from themicrocell sub-band spectrum are allocated for the CIC 101, 103, 105,107. These four frequencies include an uplink 101 from TSFD wirelessComDocs 900 to PSE 600, an uplink 103 from PSE 600 to PNE 800, adownlink 105 from PNE 800 to PSE 600, and a downlink 107 from PSE 600 toTSFD wireless ComDocs 900. The CIC uplink 101 is a random access channelwhereby the TSFD wireless ComDocs 900 within a microcell compete for itsuse. The TSFD wireless ComDocs 900 listen for activity on the CICdownlink 107 from the PNE 800 and transmit a call initiation requestwhen the channel is clear. Request messages include the TSFD wirelessComDoc address (identification number) and the request information.Response messages include the TSFD wireless ComDoc address along withrequested information or simple acknowledgement depending on therequest. If a downlink response is not received when expected, then theTSFD wireless ComDoc 900 will repeat its request following a randomlydetermined delay period. The delay period is intended to preventcollisions with transmissions from competing TSFD wireless ComDocs 900and TSFD wireless handsets 300 on the shared uplink. The followingfunctions are handled on the CIC:

The following functions are handled on the CIC:

-   -   TSFD wireless handset 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDoc 900 and TSFD wireless X-DatCom 400 initial        registration to PNE 800    -   TSFD wireless handset 300, TSFD wireless ComDoc 900, TSFD        wireless X-DatCom 400 and PC-DatCom card periodic registration        refresh to PNE 800    -   TSFD wireless handset 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDoc 900 and TSFD wireless X-DatCom 400        authorization and short id assignment to TSFD wireless handset        300, TSFD wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900        and TSFD wireless X-DatCom 400    -   Call request to PNE 800 or to TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 and TSFD        wireless X-DatCom 400    -   Call frequency assignment to TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 and TSFD        wireless X-DatCom 400    -   Call progress prior to voice/data channel use to TSFD wireless        handset 300, TSFD wireless PC-DatCom Cards 500, TSFD wireless        ComDoc 900 and TSFD wireless X-DatCom 400    -   Acknowledgements to PNE 800 or to TSFD wireless handset 300,        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 and TSFD        wireless X-DatCom 400

TSFD wireless handset 300, TSFD wireless PC-DatCom Cards 500, TSFDwireless ComDoc 900 and TSFD wireless X-DatCom 400 ID, either anelectronic serial number (ESN) or phone number, is 40 bits. When a TSFDwireless handset 300, TSFD wireless PC-DatCom Cards 500, TSFD wirelessComDoc 900 or TSFD wireless X-DatCom 400 initially registers in a newmicrocell, it will be assigned an 8-bit temporary ID for use whileregistered with that microcell. The shorter ID significantly reducesmessage lengths on the RC, CIC, and CMC where \ TSFD wireless handset300, TSFD wireless PC-DatCom Cards 400, TSFD wireless ComDoc 900 andTSFD wireless X-DatCom 400 addresses are required.

In an alternate embodiment of the present invention FIG. 13, a sharedCall Maintenance Channel (CMC) 102, 104, 106, 108 is used in eachmicrocell for out-of-band signaling functions once a call has beenestablished. Four fixed physical frequencies from the microcell sub-bandspectrum are allocated for the CMC 102, 104, 106, 108. These include anuplink 102 from TSFD wireless ComDocs 900 to PSE 600, an uplink 104 fromPSE 600 to PNE 800, a downlink 106 from PNE 800 to PSE 600, and adownlink 108 from PSE 600 to TSFD wireless ComDocs 900. The CMC uplink102 is a random access channel whereby the TSFD wireless ComDocs 900 andTSFD wireless handsets 300 within a microcell compete for its use, justlike the CIC uplink. The following functions are handled on the CMC:

-   -   Call completion to PNE 800    -   Call handoff request to PNE 800    -   911 position report to PNE 800    -   Call handoff frequency to a TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 or TSFD        wireless X-DatCom 400    -   Call waiting notification to a TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 or TSFD        wireless X-DatCom 400    -   Voice message notification to a TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 or TSFD        wireless X-DatCom 400    -   Text message notification to a TSFD wireless handset 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 or TSFD        wireless X-DatCom 400    -   Acknowledgements to PNE 800 or to a TSFD wireless handset 300,        TSFD wireless PC-DatCom Cards 500, TSFD wireless ComDoc 900 or        TSFD wireless X-DatCom 400

When a CMC message is pending for a TSFD wireless ComDoc 900, the PNE800 transmits an attention code for the TSFD wireless ComDoc 900 on theRC. Since the RC is periodically monitored by the TSFD wireless ComDoc900, even while it is on a call, the TSFD wireless ComDoc 900 is able toidentify the attention code and then monitor the CMC downlink 108 forthe message. When the TSFD wireless ComDoc 900 uses the CMC, it drops a40-ms voice frame in order to use the channel. Consequently, CMC usagemust be infrequent and messages should be sized to fit within a singlevoice frame. If no response is received to a TSFD wireless ComDocrequest, the request will be retransmitted on another frame after arandom delay. Subsequent frames are selected randomly, but the droppingof back-to-back frames is precluded.

System Components

I. TSFD Wireless Handsets

Turning now to FIG. 14, FIG. 14 shows a block diagram 120 of anembodiment of a TSFD wireless handset 300. The TSFD wireless handset 300includes a transceiver 310 and antenna 312. The transceiver 310 consistsof two receivers, one transmitter, and two programmable frequencysynthesizers. The antenna 312 may be integrated into the transceiver, ormay be a modular type that plugs into the case. The transceiver transmitpower is adjustable in 3 dB steps over a 50 dB range relative to themaximum transmit power. The gain of the transceiver antenna 312 is inthe range of 0 to 2.5 dB under controlled conditions. The transceiver310 is capable of simultaneously receiving and demodulating two signalson independently programmed frequencies. The transceiver architectureincludes an 80-MHz offset oscillator to facilitate switching betweentransmit and receive operations on a single channel pair without needingto re-program a frequency synthesizer. A processor 320 providescentralized control to the TSFD wireless handset 300 and includes adigital signal processing (DSP) 322 for demodulating signals, acontroller 324 for display/keypad servicing, permanent memory 326,non-volatile memory 328, and volatile memory 330. Firmware is embeddedin the processor memory to implement protocols, control the userinterfaces for the display, keypad, menus, etc., and control theapplication program interface (API) for the secondary mode (roaming)protocol. The firmware includes a bootstrap loader that is stored inpermanent memory 326 to enable download of the main code. The main codeis stored in non-volatile memory 328 so that it is not lost in theabsence of power, but can be overwritten by subsequent downloads, e.g.,firmware updates. In addition to the main code, there also exist anumber of configuration variables that are downloaded to activate theTSFD wireless handset 300. These configuration variables set the user'sphone number and services subscribed, and are also stored innon-volatile memory. The handset firmware also manages non-volatile usermemory for storage of phone book names and numbers, received textmessages, and the current operating mode selections (ringer volume/type,beep volume, etc.). The Processor 320 shall have peripheral interfacesto the following elements:

In an alternate embodiment of the invention, the Induction Coupled DataLine is disclosed thus: this line attaches to the recharger and mayimport and export data from a TSFD wireless handset via inductivecoupling 390 through the environmental package (case). The handsetenvironmental package integrity can be preserved when entering data viathe induction coil 390 which is also used for the recharging of theinternal batteries. The integrity of the environmental package can bemaintained via the induction coil 390 through the case of theenvironmental package without any external metal contact. ExternallyDirect LEDs: These LEDs 396 are included to give the handset userexternal illumination. The LEDs 396 are in effect, a processorcontrolled-keypad controlled, flashlight with auto-off features.Earphone and Microphone Induction Coupled Coils 395: These internal casecoils couple earphone and microphone function to a headset wherein thehandset case is of the sealed, water tight variety. Digital Recorder397: This device chip enables the processor to activate a fullyfunctional digital recorder within the TSFD wireless handset 300.Processor interface gives the recorder access to call recording,external-to-the-case recording via the handset microphone or remoteactivation of recorder functions via another TSFD Protocol wirelessdevice so coded for such action.

Vocoder 340

E-911 position locator 350

Transceiver 310

Keypad 362

Display 360

Power Manager 370

Roaming Transceiver 380

External Data Interface 390

Miscellaneous controls include ringer 366, LED 367 and vibrator 368, MP3Dedicated Memory 399, Induction Coupled Mic and Earphone coilconnections 395, external hookup for external mic and speaker 398,digital recorder module 397, Digital Camera “A” 385 and Digital Camera“B” 386. Permanent memory 326 is utilized for the processor bootstrapfirmware and electronic serial number. Each TSFD wireless handset 300contains a unique electronic serial number in permanent memory 326. Theserial number permits a minimum of 1 billion unique serial numbers.Bootstrap software is also contained in permanent memory 326 to enabledownload of the operational software through the TSFD wireless handsetexternal data port. The nonvolatile read/write memory 328 is used forstoring initialization parameters and phone book data so that batteryremoval or replacement does not require re-initializationinitialization. Each handset contains its phone number in non-volatilememory. The operational software is downloadable to change features orotherwise update the code. The operational software is stored innon-volatile memory 328. The operational software is downloadable usingcapabilities of the bootstrap software, the external data port 390, andexternal software. The TSFD wireless handset 300 is capable ofmaintaining user data in non-volatile memory 328, such as phone bookentries. The TSFD wireless handset 300 includes a vocoder (voicecoder/decoder) 340 for processing the digitized voice signals. Thevocoder 340 compresses and channel code the digitized voice data inorder to meet the voice quality requirement and to enable implementationof the RF and communication protocols. The TSFD wireless handset 300includes a microphone/speaker interface 391 for interfacing a microphone389 and speaker 392 to other handset components. The TSFD wirelesshandset 300 may accept an external microphone input signal and shallprovide an external speaker output signal. The TSFD wireless handset 300includes a power manager 370 to assist in extending battery life. TheTSFD wireless handset 300 includes a rechargeable battery 393, but isalso capable of connection to an external 11-16 Vdc power source throughan external power interface 394. The TSFD wireless handset 300 includesa roaming transceiver 380 to serve as an optional secondary or alternatemode to the TSFD wireless communication system described. The roamingtransceiver 380 implements one or more of the following standardwireless protocols:

PCS CDMA (IS-95)

PCS TDMA (IS-136)

GSM 1900

AMPS

Bluetooth

WiFi (optional)

The roaming transceiver 380 includes functions for an antenna, RFtransceiver, protocol processing, and vocoder processing. The TSFDwireless handset 300 may also include a position locator 350 function tosupport the enhanced 911 (E911) requirements.

In an alternate embodiment of the present invention, the TSFD wirelesshandset 300 performs as a wireless hub/modem for WiFi, TSFD CCAP orCCAP+. This arrangement allows for a TSFD wireless handset 300 and astandard laptop to create a link to any data source or external networkthrough the TSFD wireless handset 300 exclusively. In this alternatemode of operation, the TSFD wireless handset 300 acts as a master accesspoint to any one of several networks for an ordinary laptop with astandard WiFi card.

In an alternate embodiment of the present invention, the TSFD wirelesshandset 300 (or any other TSFD wireless Mobile device) may performstandard PCS music and ringtone downloads from the TSFD network or fromnetworks other than the TSFD network while operating within the roamingtransceiver mode.

Further, another embodiment of the invention describes: the positioningof Digital Cameras “A” 385 and Digital Camera “B” 386 on the case/bodyof the TSFD wireless handset whereas camera 385 and camera 386 areforward-looking in the same direction, the same inclination and in thesame side to side positioning such that a true stereoscopic image madebe obtained through the capturing of both digital signals. The encodingof the separate signals shall be such that the signals can be sent toother TSFD wireless devices enabled to receive these stereoscopicimages. The display of such images can be made through the attachment ofa device for the stereoscopic display of video images; i.e., a virtualreality viewing headset for such purposes. The transmission and thereceipt of these stereoscopic digital images shall be made through theTSFD Sub-Protocol IDDT (Integrated Direct Data Transfer) on the TSFDnetwork exclusively. Single still or video captured images may beobtained from digital camera “A” 385 where there is no need to capturestereoscopic images. The transfer of such still or prerecorded digitalimages from camera “A” only, may be made on the standard TSFD voicebandwidth, or with the TSFD CCAP or CCAP+routines as defined in FIG. 8or FIG. 9.

II. The TSFD Wireless Communication Docking Bays

Turning now to FIG. 15, FIG. 15 shows a block diagram of an embodimentof a TSFD wireless Communication Docking Bay (TSFD wireless ComDoc) 900.The TSFD wireless ComDoc 900 includes all the features and functions ofa TSFD wireless handset 300, as described above and shown in FIG. 14.The TSFD wireless ComDoc 900 includes a transceiver 940 and antenna 942.The transceiver 940 consists of two receivers, one transmitter, and twoprogrammable frequency synthesizers. The antenna 942 may be integratedinto the transceiver 940, or may be a modular type that plugs into theunit. The transceiver 940 transmit power is adjustable in 3 dB stepsover a 50 dB range relative to the maximum transmit power. The gain ofthe transceiver antenna 942 is in the range of 0 to 2.5 dBi undercontrolled conditions. The transceiver 940 is capable of simultaneouslyreceiving and demodulating two signals on independently programmedfrequencies. The transceiver architecture includes an 80-MHz offsetoscillator to facilitate switching between transmit and receiveoperations on a single channel pair without needing to re-program afrequency synthesizer. A processor 910 provides centralized control tothe TSFD wireless ComDoc 900 and includes a digital signal processing(DSP) 912 for demodulating signals, a controller 914 for display/keypadservicing, and permanent, non-volatile and volatile memory 916. Firmwareis embedded in the processor memory to implement protocols, control theuser interfaces for the display, keypad, menus, etc., and control theapplication program interface (API) for the secondary mode protocol. Thefirmware includes a bootstrap loader that is stored in permanent memory916 to enable download of the main code. The main code is stored innon-volatile memory 916 so that it is not lost in the absence of power,but can be overwritten by subsequent downloads, e.g., firmware updates.In addition to the main code, there also exist a number of configurationvariables that are downloaded to activate the TSFD wireless ComDoc 900.These configuration variables set the user's phone number and servicessubscribed, and are also stored in non-volatile memory. The handsetfirmware also manages non-volatile user memory for storage of phone booknames and numbers, received text messages, and the current operatingmode selections (ringer volume/type, beep volume, etc.). The Processor910 shall have peripheral interfaces to the following elements:

Vocoder 944

Transceiver 940

Keypad 920

Display 922

Power Manager 930

Secondary Transceiver 950

Notification Device Interface 924

Digital Camera “A” 985

Digital Camera “B” 986

Permanent memory 916 is utilized for the processor bootstrap firmwareand electronic serial number. Each TSFD wireless ComDoc 900 contains aunique electronic serial number in permanent memory 916. The serialnumber permits a minimum of 1 billion unique serial numbers. Bootstrapsoftware is also contained in permanent memory 916 to enable download ofthe operational software through an external data port 958. Thenonvolatile read/write memory 916 is used for storing initializationparameters and phone book data so that battery removal or replacementdoes not require re-initialization. Each TSFD wireless ComDoc containsits phone number in non-volatile memory. The operational software isdownloadable to change features or otherwise update the code. Theoperational software is stored in non-volatile memory 916. Theoperational software is downloadable using capabilities of the bootstrapsoftware, an external data port, and external software. The TSFDwireless ComDoc is capable of maintaining user data in non-volatilememory 916, such as phone book entries. The TSFD wireless ComDocincludes a vocoder (voice coder/decoder) 944 for processing thedigitized voice signals. The vocoder 944 compresses and channel code thedigitized voice data in order to meet the voice quality requirement andto enable implementation of the RF and communication protocols. The TSFDwireless ComDoc 900 includes a microphone 946 and speaker 948. The TSFDwireless ComDoc 900 may accept an external microphone input signal andshall provide an external speaker output signal. The TSFD wirelessComDoc 900 includes a power manager 930 to assist in extending batterylife. The TSFD wireless ComDoc 900 includes a rechargeable battery 934,but is also capable of connection to an external power source through anexternal power interface. The TSFD wireless ComDoc 900 includes anoptional secondary transceiver 950 to serve as a secondary or alternatemode to the TSFD wireless communication system described. The secondarytransceiver implements one or more of the following standard wirelessprotocols:

PCS CDMA (IS-95)

PCS TDMA (IS-136)

GSM 1900

AMPS

BLUETOOTH

WIFI

The secondary transceiver 950 includes functions for an antenna, RFtransceiver, protocol processing, and vocoder processing. The TSFDwireless ComDoc 900 also includes provisions for a position locatorfunction to support the enhanced 911 (E911) requirements if needed. TheTSFD wireless ComDoc 900 includes a PSTN line capture module 952 forconnection to one or more PSTN lines. This enables multiple telephonejacks to be provided on the TSFD wireless ComDoc 900 for connectingfixed telephone handsets 956 and computer modems to the PSTN lines 954.In addition to an audio annunciator 926 and a visual indicator 928, theTSFD wireless ComDoc 900 provides handset recharge bays 932.

Turning again to FIG. 16, FIG. 16 shows optional features that may beadded to the TSFD wireless ComDoc 900 to expand its capability.Communication interfaces include an infrared data interface 960, aBluetooth interface 968, a LAN/cable modem interface 970, a PSTN modeminterface 980, and an external antenna interface 982 for the wirelesscommunications network. User interfaces include an external keyboardinterface 962, an external video monitor interface 964, and a videocamera interface 966. Interfaces to locator equipment include an E-911position locator interface 972 and a GPS position locator interface 974.Storage device interfaces include a hard drive interface 976 and aCD/DVD drive interface 978.

Further disclosing embodiments of this invention, the TSFD wirelessComDoc 900 may have additional features similar to those in the TSFDwireless X-DatCom shown in FIG. 18 which are not shown in FIG. 15 orFIG. 16. For example, the TSFD wireless ComDoc 900 may include theconnection of the power manager 930 to an external power source throughan external power interface or through an inductive coupled rechargecoil. The TSFD wireless ComDoc environmental package of integrity can bepreserved when entering data via the induction coupling coil which isalso used for the recharging of the internal batteries. The integrity ofthe environmental package can be maintained via the induction coilthrough the case of the environmental package without any external metalcontact.

In an alternate embodiment of the present invention, the TSFD wirelessComDoc 900 can exercise an Operational Static State Control or anOperational Dynamic State Control. It can express the functionality of a“Convergence” as well as “Divergence” device, i.e., ON network or OFFnetwork. It can act as a simple TSFD or a traditional PSC wirelessdevice, allowing the user to make ordinary wireless calls on any of amultiple of networks; i.e., TSFD or PCS Style: (PCS, AMPS, TDMA, CDMA)determined by whatever contract the user may have with wireless carrierprovider. The TSFD wireless ComDoc enables TSFD wireless network usersto access a multiple of external networks; i.e., cable Internet, PSTNLandline, WiFi, LANs, other computers, etc. The device has an internalhard drive, a PCS antenna, external antenna interface as furtherilluminated in FIG. 15.

Operational Static State Control by a TSFD Wireless ComDoc:

-   -   1. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a PC Home        Computer via the TSFD wireless ComDoc's peripheral interface        connections.    -   2. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a cable modem for        access by the TSFD wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   3. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a PSTN/DSL modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   4. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a LAN modem for        access by the TSFD wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   5. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an External Hard        Drive for the retrieval of digital data via the TSFD wireless        ComDoc's peripheral interface connections.    -   6. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a CD/DVD Drive        for the retrieval of digital data via the TSFD wireless ComDoc's        peripheral interface connections.    -   7. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an Infrared Data        Sensor via the TSFD wireless ComDoc's peripheral interface        connections.    -   8. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an External Video        Camera via the TSFD wireless ComDoc's peripheral interface        connections.    -   9. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a PC Home        Computer via the TSFD wireless ComDoc's peripheral interface        connections.    -   10. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a cable modem for        access by the PCS wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   11. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a PSTN/DSL modem        for access by the PCS wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   12. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a LAN modem for        access by the PCS wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   13. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an External Hard        Drive for the retrieval of digital data via the TSFD wireless        ComDoc's peripheral interface connections.    -   14. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of a CD/DVD Drive        for the retrieval of digital data via the TSFD wireless ComDoc's        peripheral interface connections.    -   15. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an Infrared Data        Sensor via the TSFD wireless ComDoc's peripheral interface        connections.    -   16. A PCS wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Static State Control of an External Video        Camera via the TSFD wireless ComDoc's peripheral interface        connections.        Operational Dynamic State Control by a TSFD Wireless ComDoc 900:    -   1. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of a PC Home        Computer via the TSFD wireless ComDoc's peripheral interface        connections.    -   2. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of a cable modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   3. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of a PSTN/DSL modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   4. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of a LAN modem for        access by the TSFD wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   5. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of an External Hard        Drive for the retrieval of digital data via the TSFD wireless        ComDoc's peripheral interface connections.    -   6. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of a CD/DVD Drive        for the retrieval of digital data via the TSFD wireless ComDoc's        peripheral interface connections.    -   7. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of an Infrared Data        Sensor via the TSFD wireless ComDoc's peripheral interface        connections.    -   8. A TSFD wireless device is used to command a TSFD wireless        ComDoc 900 to exercise Dynamic State Control of an External        Video Camera via the TSFD wireless ComDoc's peripheral interface        connections.    -   9. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of a PC Home Computer via the TSFD wireless        ComDoc's peripheral interface connections.    -   10. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of a cable modem for access by the PCS, TDMA,        CDMA, AMPS or GSM protocol wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   11. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of a PSTN/DSL modem for access by the PCS, TDMA,        CDMA, AMPS or GSM protocol wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   12. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of a LAN modem for access by the PCS, TDMA, CDMA,        AMPS or GSM protocol wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   13. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of an External Hard Drive for the retrieval of        digital data via the TSFD wireless ComDoc's peripheral interface        connections.    -   14. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of a CD/DVD Drive for the retrieval of digital        data via the TSFD wireless ComDoc's peripheral interface        connections.    -   15. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of an Infrared Data Sensor via the TSFD wireless        ComDoc's peripheral interface connections.    -   16. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless ComDoc 900 to exercise Dynamic        State Control of an External Video Camera via the TSFD wireless        ComDoc's peripheral interface connections.

Further, an additional embodiment of the invention describes: thepositioning of Digital Cameras “A” 985 and Digital Camera “B” 986 on thecase/body of the TSFD wireless TSFD wireless ComDoc 900 whereas; camera485 and camera 986 are forward-looking in the same direction, the sameinclination and in the same side to side positioning such that a truestereoscopic image made be obtained through the capturing of bothdigital signals. The encoding of the separate signals shall be such thatthe signals can be sent to other TSFD wireless devices enabled toreceive these stereoscopic images. The display of such images can bemade through the attachment of a device for the stereoscopic display ofvideo images; i.e., a virtual reality viewing headset for such purposes.The transmission and the receipt of these stereoscopic digital imagesshall be made through the TSFD Sub-Protocol IDDT (Integrated Direct DataTransfer) on the TSFD network exclusively. Single still or videocaptured images may be obtained from digital camera “A” 985 where thereis no need to capture stereoscopic images. The transfer of such still orprerecorded digital images from camera “A” only, may be made on thestandard TSFD voice bandwidth, or with the TSFD CCAP or CCAP+ routinesas defined in FIG. 8 or FIG. 9.

Turning now to FIG. 17, FIG. 17 shows examples of prefix codes that maybe used to access TSFD wireless ComDoc functions. To access a function,one of the four-digit prefix codes presented in FIG. 17 must be enteredprior to entering a TSFD wireless handset access number. The accesscodes are meant to be examples of means for accessing availablefunctions in the TSFD wireless ComDoc through a TSFD wireless handsetkeyboard. The present TSFD wireless ComDoc invention is a uniqueexternal networks interface that may be deployed in a home or businessas a fixed-base device. It is primarily composed of a fully functionalTSFD wireless handset circuitry and numerous internal peripheral devicesdedicated to providing multiple external interface paths for a wirelessnetwork. The device can stand alone as a fixed-base wireless set havingits own wireless telephone number, can function as a handset-to-externalnetworks relay system, can serve as a home-based high-speed accessdevice to wireless broadband Internet service for home computers, andcan serve as a remote access interface device for high-speed wirelessbroadband Internet service between handset-laptop computer combinationsand home installed broadband Internet connection. It has several otherunique capabilities such as serving as a home intercom system forextension phones, a speakerphone, security system wireless PSTN 19connection in the event of PSTN 19 line failure, and interface withBluetooth/IR devices in the home for wireless remote control of “SmartHouse” technology. A novel feature of the TSFD wireless ComDoc 900 is tobe a backup communications path to the PSTN 19 for any wireless handsetsubscriber who also has permanent access to a PSTN 19 landline in theirhome or business within the greater wireless system service area. It ismost effective however, within the range of a PSE 600 that is alsowithin range of the business or home. By using a TSFD wireless ComDoc900 connection to a PSTN 19, the calling load on the PNE 600 for accessto the PSTN 19 could be greatly reduced thus saving the wireless systemoperator monthly line charges for maintaining switch access to the PSTN19.

III. TSFD Wireless External Data Communications Modules

In alternate embodiment of the invention, an embodiment of the TSFDwireless X-DatCom 400 of the present invention, FIG. 18, is a MobileTSFD external networks interface and may be deployed in a home orbusiness as a fixed-base device. It may also be remotely placed for thecollection of data through attached sensors or devices or the TSFDwireless X-DatCom 400 may be employed to remotely control the limited ortotal operational state of an external device attached to the TSFDwireless X-DatCom 400. It is primarily composed of a fully functionalTSFD Protocol handset circuitry and numerous internal peripheral devicesdedicated to providing multiple external interface paths for a wirelessnetwork or for the collection of data or the remote control of externaldevices. The device can stand alone as a fixed-base wireless set havingits own wireless telephone number, can function as a handset-to-externalnetworks relay system, can serve as a home-based high-speed accessdevice to wireless broadband Internet service for home computers, andcan serve as a remote access interface device for high-speed wirelessbroadband Internet service between handset-laptop computer combinationsand home installed broadband Internet connection. It has several othercapabilities such as serving as a speakerphone, security system wirelessPSTN 19 connection in the event of PSTN 19 line failure, and interfacewith Bluetooth/IR devices in the home or office for wireless remotecontrol of “Smart House” technology. A feature of the TSFD wirelessX-DatCom 400 is to be a backup communications path to the PSTN19 for anywireless handset subscriber who also has permanent access to a PSTNlandline in their home or business within the greater wireless systemservice area. It is most effective however, within the range of a PSE600 that is also within range of the business or home. By using a TSFDwireless X-DatCom 400 connection to a PSTN, the vast quantities of datacould be remotely collected, numerous and varied devices could beremotely controlled and access to otherwise inaccessible externalnetworks could be achieved by TSFD Protocol devices associated withparticular TSFD wireless X-DatCom 400 devices.

Turning now to FIG. 18, a block diagram 130 of a TSFD wireless X-DatCom400 is shown. The TSFD wireless X-DatCom 400 includes all the featuresand functions of a TSFD wireless handset 300 as described in FIG. 14,and many of those found in a TSFD wireless TSFD wireless ComDoc 900 inFIG. 15. The TSFD wireless X-DatCom 400 includes a transceiver 410 andantenna 412. The transceiver 410 consists of two receivers, onetransmitter, and two programmable frequency synthesizers. The antenna412 may be integrated into the transceiver, or may be a modular typethat plugs into the unit. The transceiver transmit power is adjustablein 3 dB steps over a 50 dB range relative to the maximum transmit power.The gain of the transceiver antenna 412 is in the range of 0 to 2.5 dBiunder controlled conditions. The transceiver 410 is capable ofsimultaneously receiving and demodulating two signals on independentlyprogrammed frequencies. The transceiver architecture includes an 80-MHzoffset oscillator to facilitate switching between transmit and receiveoperations on a single channel pair without needing to re-program afrequency synthesizer. A processor 420 provides centralized control tothe TSFD wireless X-DatCom 400 and includes a digital signal processing(DSP) 422 for demodulating signals, a controller 424 for display/keypadservicing, and permanent, non-volatile and volatile memory 426. Firmwareis embedded in the processor memory to implement protocols, control theuser interfaces for the display, keypad, menus, etc., and control theapplication program interface (API) for the secondary mode protocol. Thefirmware includes a bootstrap loader that is stored in permanent memory426 to enable download of the main code. The main code is stored innon-volatile memory 428 so that it is not lost in the absence of power,but can be overwritten by subsequent downloads, e.g., firmware updates.In addition to the main code, there also exist a number of configurationvariables that are downloaded to activate the TSFD wireless X-DatCom400. These configuration variables set the user's phone number andservices subscribed, and are also stored in non-volatile memory. TheTSFD wireless X-DatCom 400 firmware also manages non-volatile usermemory for storage of phone book names and numbers. The Processor 420shall have peripheral interfaces to the following elements:

Vocoder 440

Transceiver 410

Keypad 462

Display 460

Power Manager 470

Secondary Transceiver 480

Digital Camera “A” 485

Digital Camera “B” 485

Permanent memory 426 is utilized for the processor bootstrap firmwareand electronic serial number. Each TSFD wireless X-DatCom 400 contains aunique electronic serial number in permanent memory 426. The serialnumber permits a minimum of 1 billion unique serial numbers. Bootstrapsoftware is also contained in permanent memory 426 to enable download ofthe operational software through an external data port 490. Thenonvolatile read/write memory 428 is used for storing initializationparameters and phone book data so that battery removal or replacementdoes not require re-initialization. Each TSFD wireless X-DatCom 400contains its phone number in non-volatile memory. The operationalsoftware is downloadable to change features or otherwise update thecode. The operational software is stored in non-volatile memory 428. Theoperational software is downloadable using capabilities of the bootstrapsoftware, an external data port, and external software. The TSFDwireless X-DatCom 400 is capable of maintaining user data innon-volatile memory 428, such as phone book entries. The TSFD wirelessX-DatCom 400 includes a vocoder (voice coder/decoder) 440 for processingthe digitized voice signals. The vocoder 440 compresses and channel codethe digitized voice data in order to meet the voice quality requirementand to enable implementation of the RF and communication protocols. TheTSFD wireless X-DatCom 400 includes a microphone 402, speaker 4404, andan interface 408 for the microphone 402 and the speaker 404. The TSFDwireless X-DatCom 400 may accept an external microphone input signal andshall provide an external speaker output signal. The TSFD wirelessX-DatCom 400 includes a power manager 470 to assist in extending batterylife or facilitating input of fluctuating alternative power voltages.The TSFD wireless X-DatCom 400 includes a rechargeable battery 410, butis also capable of connection to an external power source through anexternal power interface or through the inductive coupled recharge coil490 in its case. The TSFD wireless X-DatCom 400 includes an optionalsecondary transceiver 480 to serve as a secondary or alternate mode tothe wireless communication system described. The secondary transceiverimplements one or more of the following standard wireless protocols:

PCS CDMA (IS-95)

PCS TDMA (IS-136)

GSM 1400

AMPS

The secondary transceiver 480 includes functions for an antenna, RFtransceiver, protocol processing, and vocoder processing. The TSFDwireless X-DatCom 400 also includes provisions for a position locatorfunction to support the enhanced 911 (E911) requirements if needed. TheTSFD wireless X-DatCom 400 includes a PSTN line capture module 452 forconnection to one or more PSTN lines. This enables multiple telephonejacks to be provided on the TSFD wireless X-DatCom 400 for connectingfixed telephone handsets 456 and computer modems to the PSTN lines 454.The TSFD wireless X-DatCom 400 environmental package integrity can bepreserved when entering data via the induction coil 490 which is alsoused for the recharging of the internal batteries. The integrity of theenvironmental package can be maintained via the induction coil 490through the case of the environmental package without any external metalcontact.

Static State Control of Optional Peripheral Systems via TSFD WirelessDevices:

-   -   1. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of a PC Computer        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   2. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of a cable modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   3. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of a PSTN/DSL        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   4. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of a LAN modem for        access by the TSFD wireless device to the Internet via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   5. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of an External        Hard Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   6. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of a CD/DVD Drive        for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   7. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of an Infrared        Data Sensor via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   8. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Static State Control of an External        Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   9. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of a PC Computer via the TSFD wireless X-DatCom's        optional peripheral interface connections.    -   10. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of a cable modem for access by the PCS wireless        device to the Internet via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   11. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of a PSTN/DSL modem for access by the PCS wireless        device to the Internet via the X-DatCom's optional peripheral        interface connections.    -   12. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control 400 of a LAN modem for access by the PCS wireless        device to the Internet via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   13. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of an External Hard Drive for the retrieval of        digital data via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   14. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of a CD/DVD Drive for the retrieval of digital        data via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   15. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of an Infrared Data Sensor via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   16. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Static        State Control of an External Video Camera via the TSFD wireless        X-DatCom's optional peripheral interface connections.        Dynamic State Control of Optional Peripheral Systems via        Wireless Devices    -   1. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of a PC Home        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   2. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of a cable modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   3. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of a PSTN/DSL        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   4. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of a LAN modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   5. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of an External        Hard Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   6. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of a CD/DVD Drive        for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   7. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of an Infrared        Data Sensor via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   8. A TSFD wireless device is used to command a TSFD wireless        X-DatCom 400 to exercise Dynamic State Control of an External        Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   9. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of a PC Home Computer via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   10. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of a cable modem for access by the PCS, TDMA,        CDMA, AMPS or GSM protocol wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   11. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of a PSTN/DSL modem for access by the Internal        TSFD wireless X-DatCom Software is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a        cable modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   12. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   13. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   14. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a cable modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   15. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   16. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   17. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to gain access to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   18. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of a LAN modem for access by the PCS, TDMA, CDMA,        AMPS or GSM protocol wireless device to the Internet via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   19. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of an External Hard Drive for the retrieval of        digital data via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   20. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of a CD/DVD Drive for the retrieval of digital        data via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   21. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of an Infrared Data Sensor via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   22. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless device is        used to command a TSFD wireless X-DatCom 400 to exercise Dynamic        State Control of an External Video Camera via the TSFD wireless        X-DatCom's optional peripheral interface connections.        Static State Control of Optional Peripheral Systems via the        Parallel Computing Artificial Intelligence-Based Distributive        Routing System (AIRDS) 1300    -   1. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a PC        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   2. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a        cable modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   3. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a        PSTN/DSL modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connection.    -   4. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a LAN        modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   5. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   6. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of a        CD/DVD Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   7. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   8. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Static State Control of an        External Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.        Dynamic State Control of Optional Peripheral Systems via the        Parallel Computing Artificial Intelligence-Based Distributive        Routing System 1300    -   1. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of a PC        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   2. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of a        cable modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   3. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of a        PSTN/DSL modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   4. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of a LAN        modem for access by the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   5. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   6. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of a        CD/DVD Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   7. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   8. The Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless X-DatCom 400 to exercise Dynamic State Control of an        External Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.        Static State Control of Optional Peripheral Systems via Internal        TSFD Wireless X-DatCom Software:    -   1. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        PC Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   2. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        cable modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   3. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   4. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   5. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        cable modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   6. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   7. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   8. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Static State Control of a        cable modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   9. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom to exercise Static State Control of a        PSTN/DSL modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   10. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a LAN modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   11. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a cable modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   12. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a PSTN/DSL modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   13. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a LAN modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   14. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        an External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   15. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        a CD/DVD Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   16. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        an Infrared Data Sensor via the TSFD wireless X-DatCom's        optional peripheral interface connections.    -   17. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Static State Control of        an External Video Camera via the TSFD wireless X-DatCom's        optional peripheral interface connections.        Dynamic State Control of Optional Peripheral Systems via        Internal TSFD Wireless X-DatCom Software    -   1. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a PC Computer via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   2. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a cable modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   3. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   4. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   5. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a cable modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   6. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a PSTN/DSL modem for access by a TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   7. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a LAN modem for access by a TSFD wireless device to the Internet        via the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   8. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a cable modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   9. Internal TSFD wireless X-DatCom Software is used to command a        TSFD wireless X-DatCom 400 to exercise Dynamic State Control of        a PSTN/DSL modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   10. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of a LAN modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   11. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of a cable modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   12. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of a PSTN/DSL modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   13. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of a LAN modem for access by a PCS, TDMA, CDMA, AMPS or GSM        protocol wireless device to the Internet via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   14. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of an External Hard Drive for the retrieval of digital data via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   15. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of a CD/DVD Drive for the retrieval of digital data via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   16. Internal TSFD wireless X-DatCom Software is used to command        a TSFD wireless X-DatCom 400 to exercise Dynamic State Control        of an Infrared Data Sensor via the TSFD wireless X-DatCom's        optional peripheral interface connections.

Internal TSFD wireless X-DatCom Software is used to command a TSFDwireless X-DatCom 400 to exercise Dynamic State Control of an ExternalVideo Camera via the TSFD wireless X-DatCom's optional peripheralinterface connections. In an alternate embodiment of the presentinvention, Remote Controlled Systems is defined as devices or systemsattached to a TSFD wireless X-DatCom 400 for the purposes of changingthe Operational States (Static or Dynamic) or for the purposes ofsending to or retrieving data from such attached devices. One can turn adevice on or off or one can send or receive data (or both) using a TSFDwireless X-DatCom 400 through one or more external networks or by theactivation of internal TSFD wireless X-DatCom 400 software. InternalSoftware can gather information and periodically report that informationover any of a number of external networks. Internal Software can inputinformation into some attached device periodically; i.e.; from storedinstructions in the TSFD wireless X-DatCom 400 or from data receivedfrom some such device which then triggers the TSFD wireless X-DatCom 400to respond automatically. Example: Natural Gas Well Monitoring—The TSFDwireless X-DatCom 400 can monitor the gas well for pressure changes andflow rates via well sensors attached to the TSFD wireless X-DatCom 400and the TSFD wireless X-DatCom 400 can then make such changes to theflow rate from the well as pressure reading dictate; up or down viaelectronically controlled actuators. (Reporting: can take place to someexternal network should this process need further attention)

External Activation of the TSFD wireless X-DatCom 400 can be achievedvia any number of selected external networks for the purpose of sendingremote control commands to some attached device. (Reporting back to thatnetwork device can then give feedback as to the effectiveness of thecommand.)

External Activation of the TSFD wireless X-DatCom 400 can be achievedvia any number of selected external networks for the purpose ofretrieving data accumulated from some device attached to the TSFDwireless X-DatCom 400.

Further, the TSFD wireless X-DatCom 400 may contain sensors for themonitoring of the immediate surroundings of the TSFD wireless X-DatCom400 device; i.e; dropping a TSFD wireless X-DatCom 400 device into aforest wherein the device is designed to snag on the branches of a treeand provide an “Above the Ground” monitoring of the area for forestambient moisture, temperature, barometric pressure, or visual dataacquisition via a digital camera. Reporting would be in data bursts thusconserving a lithium battery and providing extreme extended service.

The TSFD wireless X-DatCom 400 can be attached to and control ormonitor: (not a complete list and disclosing these examples does notlimit future)

Well Head Sensors and Actuators

Advertising Sign Lighting

Fire Sensors and sprinkler remote controls

Small Remote Weather Stations

In-Cab Trucker Notification Systems

In-Cab Taxi Notification Systems

Remote/Rural Railroad Crossing Signals

Soft Drink Machine Reporting Contents

Vending machines reporting till and contents

In-vehicle tracking and wireless reporting

In-vehicle remote shutdown system-antitheft

Large animal tracking-electronic tagging

Remote control of wild animal feeders

Wireless Heart Monitor/blood pressure monitor

Wireless heart defibrillator and reporting system

Large Cargo Container tracking and reporting

Remote control of lighted signage and reporting

Traffic sensors-reporting by audio and visual

Electric gate control and reporting by audio and visual

In-car driver notification system and reporting

In-classroom monitoring by audio and visual

Security system wireless interface and reporting device

Agricultural Conditions monitor: moisture, temp, barometric pressure

Hurricane/Tornado Data sensors dropped into a hurricane/tornado to radioback info

Further, an additional embodiment of the invention describes: thepositioning of Digital Cameras “A” 485 and Digital Camera “B” 486 on thecase/body of the TSFD wireless X-DatCom 400 whereas; camera 485 andcamera 486 are forward-looking in the same direction, the sameinclination and in the same side to side positioning such that a truestereoscopic image made be obtained through the capturing of bothdigital signals. The encoding of the separate signals shall be such thatthe signals can be sent to other TSFD wireless devices enabled toreceive these stereoscopic images. The display of such images can bemade through the attachment of a device for the stereoscopic display ofvideo images; ie.e, a virtual reality viewing headset for such purposes.The transmission and the receipt of these stereoscopic digital imagesshall be made through the TSFD Sub-Protocol IDDT (Integrated Direct DataTransfer) on the TSFD network exclusively. Single still or videocaptured images may be obtained from digital camera “A” 485 where thereis no need to capture stereoscopic images. The transfer of such still orprerecorded digital images from camera “A” only, may be made on thestandard TSFD voice bandwidth, or with the TSFD CCAP or CCAP+ routinesas defined in FIG. 8 or FIG. 9.

IV. Personal Computer TSFD Multi-Mode Wireless Access Cards

An alternate embodiment of the present invention, shown in FIG. 19, isan embodiment of the Personal Computer TSFD Multi-mode Wireless accesscard, also known as the TSFD Personal Computer Data Communication Card(TSFD wireless PC-DatCom) 500. The TSFD network can send and receivesignals with any TSFD wireless device within the network. A specificdevice utilizing this technology is the TSFD wireless PC-DatCom 500, acircuit board “card” suitable for plugging into a laptop PersonalComputer. Virtually every PC laptop manufacturer now offers the optionfor the computer user to insert a “WiFi card” in their computer forwireless Internet connectivity. This feature gives the user quick,wireless Internet connectivity for sending and receiving e-mail, sendingin reports, managing business or “Surfing the Web”, all without wires.WiFi is available all over the world in places called “hotspots.” Cafes,hotels, offices and homes are all converting to this convenient form ofconnectivity. Also, available, are services from such carriers asT-Mobile® and Verizon® for a dedicated subscription wireless Internetservice broadcast over an entire community or city. The TSFD network isalready designed to allow a subscriber to send and receive data at datarates of up to 1 Mbps over existing “PCS” frequencies through TSFDwireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD wirelessComDocs 900 or TSFD wireless X-DatComs 400. With the inclusion of a TSFDwireless PC-DatCom Card, the TSFD network can communicate directly withan existing PC laptop. Further, the PC-DatCom Card 500 includesmulti-mode operations: TSFD, WiFi, CDMA, TDMA, and GSM for datatransfer. Selection of network or transmission choice is made by the PClaptop user on a PC screen “popup” window. Communication to existingwall mounted IR communications terminals is also featured. Full serviceTSFD wireless telephone service can be accessed over the TSFD network,where available, with the PC Laptop card, through screen features of thePC. CCAP and CCAP+ data transfers are possible where another computer isalso fitted with the TSFD PC Laptop card and each is a TSFD Networksubscriber.

In another embodiment of the present invention, FIG. 19—diagram 140, aTSFD wireless PC-DatCom Card's operational methodologies and componentsare shown. The TSFD wireless PC-DatCom Card 500 includes all thefeatures and functions of a TSFD wireless handset as described in FIG.14, and many of those found in a TSFD wireless ComDoc in FIG. 15 and theTSFD wireless X-DatCom of FIG. 18. The TSFD wireless PC-DatCom Card 500includes a transceiver 510 and antenna 512. The transceiver 510 consistsof two receivers, one transmitter, and two programmable frequencysynthesizers. The antenna 512 may be integrated into the transceiver, ormay be a modular type that plugs into the unit. The transceiver transmitpower is adjustable in 3 dB steps over a 50 dB range relative to themaximum transmit power. The gain of the transceiver antenna 512 is inthe range of 0 to 2.5 dBi under controlled conditions. The transceiver510 is capable of simultaneously receiving and demodulating two signalson independently programmed frequencies. The transceiver architectureincludes an 80-MHz offset oscillator to facilitate switching betweentransmit and receive operations on a single channel pair without needingto re-program a frequency synthesizer. A processor 520 providescentralized control to the TSFD wireless PC-DatCom Card 500 and includesa digital signal processing (DSP) 522 for demodulating signals, acontroller 524 for display/keypad servicing, and permanent, non-volatileand volatile memory 526. Firmware is embedded in the processor memory toimplement protocols, control the user interfaces for the display,keypad, menus, etc., and control the application program interface (API)for the secondary mode protocol. The firmware includes a bootstraploader that is stored in permanent memory 526 to enable download of themain code. The main code is stored in non-volatile memory 528 so that itis not lost in the absence of power, but can be overwritten bysubsequent downloads, e.g., firmware updates. In addition to the maincode, there also exist a number of configuration variables that aredownloaded to activate the TSFD wireless PC-DatCom Card 500. Theseconfiguration variables set the user's phone number and servicessubscribed, and are also stored in non-volatile memory. The TSFDwireless PC-DatCom Card 500 firmware also manages non-volatile usermemory for storage of phone book names and numbers. The Processor 520shall have peripheral interfaces to the following elements:

Vocoder 540

Transceiver 510

Keypad 562

Display 560

Power Manager 570

Secondary Transceiver 580

Permanent memory 526 is utilized for the processor bootstrap firmwareand electronic serial number. Each TSFD wireless PC-DatCom Card 500contains a unique electronic serial number in permanent memory 426. Theserial number permits a minimum of 1 billion unique serial numbers.Bootstrap software is also contained in permanent memory 526 to enabledownload of the operational software through an external data port 590.The nonvolatile read/write memory 528 is used for storing initializationparameters and phone book data so that battery removal or replacementdoes not require re-initialization. Each TSFD wireless PC-DatCom Card500 contains its phone number in non-volatile memory. The operationalsoftware is downloadable to change features or otherwise update thecode. The operational software is stored in non-volatile memory 528. Theoperational software is downloadable using capabilities of the bootstrapsoftware, an external data port, and external software. The TSFDwireless PC-DatCom Card 500 is capable of maintaining user data innon-volatile memory 528, such as phone book entries. The TSFD wirelessPC-DatCom Card 500 includes a vocoder (voice coder/decoder) 540 forprocessing the digitized voice signals. The vocoder 540 compresses andchannel code the digitized voice data in order to meet the voice qualityrequirement and to enable implementation of the RF and communicationprotocols. The TSFD wireless PC-DatCom Card 500 includes a microphone502, speaker 504, and an interface 508 for the microphone 502 and thespeaker 504. The TSFD wireless PC-DatCom Card 500 may accept an externalmicrophone input signal and shall provide an external speaker outputsignal. The TSFD wireless PC-DatCom Card 500 includes a power manager570 to assist in extending battery life or facilitating input offluctuating alternative power voltages. The TSFD wireless PC-DatCom Card500 includes a rechargeable battery 510, but is also capable ofconnection to an external power source through an external powerinterface or through the inductive coupled recharge coil 590 in itscase. The TSFD wireless PC-DatCom Card 500 includes an optionalsecondary transceiver 580 to serve as a secondary or alternate mode tothe wireless communication system described. The secondary transceiverimplements one or more of the following standard wireless protocols:

PCS CDMA (IS-95)

PCS TDMA (IS-136)

GSM 1400

AMPS

The Wireless Fidelity (WiFi) Personal Computer protocol is also includedfor broadband communications and the TSFD proprietary Red Fang Protocolfor ultra-broadband, ultra short range communications.

The secondary transceiver 580 includes functions for an antenna, RFtransceiver, protocol processing, and vocoder processing. The TSFDwireless PC-DatCom Card 500 also includes provisions for a positionlocator function to support the enhanced 911 (E911) requirements ifneeded. The TSFD wireless PC-DatCom Card 500 includes an optional PSTNline capture module 452 for connection to one or more PSTN lines. Thisoption enables a telephone jack to be provided on the TSFD wirelessPC-DatCom Card 500 for connecting fixed telephone handsets 456 andcomputer modems to the PSTN lines 554.

In a further embodiment of this invention, this technology reveals afunctionality unknown in any other wireless WiFi PC card technology,i.e., the control of other major wireless systems, when utilizingcarefully controlled, coded or encrypted access.

Operational Static State Control by the TSFD Wireless PC-DatCom 500

-   -   1. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of a PC Home        Computer via the TSFD wireless ComDoc's peripheral interface        connections.    -   2. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of a cable        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   3. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of a PSTN/DSL        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   4. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of a LAN modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   5. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of an External        Hard Drive for the retrieval of digital data via the TSFD        wireless ComDoc's peripheral interface connections.    -   6. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        ComDoc's peripheral interface connections.    -   7. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of an Infrared        Data Sensor via the TSFD wireless ComDoc's peripheral interface        connections.    -   8. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Static State Control of an External        Video Camera via the TSFD wireless ComDoc's peripheral interface        connections.    -   9. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of a PC Home Computer via the TSFD wireless        ComDoc's peripheral interface connections.    -   10. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless handset is        used to command a TSFD wireless ComDoc to exercise Static State        Control of a cable modem for access by the PCS, TDMA, CDMA, AMPS        or GSM protocol wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   11. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of a PSTN/DSL modem for access by the PCS,        TDMA, CDMA, AMPS or GSM protocols wireless device to the        Internet via the TSFD wireless ComDoc's peripheral interface        connections.    -   12. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of a LAN modem for access by the PCS, TDMA,        CDMA, AMPS or GSM protocols wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   13. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of an External Hard Drive for the retrieval        of digital data via the TSFD wireless ComDoc's peripheral        interface connections.    -   14. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of a CD/DVD Drive for the retrieval of        digital data via the TSFD wireless ComDoc's peripheral interface        connections.    -   15. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of an Infrared Data Sensor via the TSFD        wireless ComDoc's peripheral interface connections.    -   16. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Static State Control of an External Video Camera via the TSFD        wireless ComDoc's peripheral interface connections.    -   17. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Static State Control of a PC Home        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   18. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Static State Control of a cable        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   19. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Static State Control of a PSTN/DSL        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   20. A Personal TSFD wireless PC-DatCom 500 is used to command a        TSFD wireless X-DatCom to exercise Static State Control of a LAN        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   21. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Static State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   22. A TSFD wireless PC-DatCom 500 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   23. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Static State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   24. A Personal Computer TSFD Multi-mode Wireless access card        (TSFD wireless PC-DatCom) 500 is used to command a TSFD wireless        X-DatCom to exercise Static State Control of an External Video        Camera via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   25. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless X-DatCom to        exercise Static State Control of a PC Home Computer via the TSFD        wireless X-DatCom's optional peripheral interface connections.    -   26. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless X-DatCom to        exercise Static State Control of a cable modem for access by the        TSFD wireless handset operating in any one of the following        alternate protocols: PCS, TDMA, CDMA, AMPS or GSM protocols to        the Internet via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   27. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by predetermined and defined software parameters        stored in the PNECP's internal Memory.    -   28. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by external instructions from a keypad, touch-active        video screen within the PNE 800 housing or by such portable data        storage medium as will facilitate uploading new data control        instructions when inserted in the PNECP's data drives.    -   29. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless and sets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        TSFD Network.    -   30. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        PSTN, the Internet, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   31. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by transmissions from the Parallel Computing        Artificial Intelligence-based Distributive Routing Computer        located within the Environmental Housing of the Network        Extender.    -   32. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Static State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by transmissions from an Parallel Computing        Artificial Intelligence-based Distributive Routing Computer        located within the TSFD Network Extender's operational service        area of captive Signal extenders 600 during a catastrophic        failure within the TSFD Network.    -   33. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor (PNECP);        wherein the PNCEP is composed of PNE Central Processors 830 a &        830 b comprising a whole and complete PNE Central Processor        system, to exercise Static State Control over the Subscriber        Database, located on a website on the Internet, containing all        TSFD wireless handsets 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP's internal        Memory.    -   34. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor (PNECP);        wherein the PNCEP is composed of PNE Central Processors 830 a &        830 b comprising a whole and complete PNE Central Processor        system, to exercise Static State Control over the Subscriber        Database, located on a website on the Internet, containing all        TSFD wireless handsets 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        NE housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP's data drives.    -   35. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the TSFD Network.    -   36. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the PSTN, the Internet,        direct copper connections using DS-1 connections, direct fiber        connections using OC-3 links, radio links with the DS-1        hardware, an Earth-Satellite ground station for direct two-way        communications with telecom satellites, the sending and        receiving of short haul, ultra-wide-band optical communications        via modulated Laser links.    -   37. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges from programming        instructions received by transmissions from the Parallel        Computing Artificial Intelligence-based Distributive Routing        Computer located within the Environmental Housing of the Network        Extender.    -   38. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges from programming        instructions received by transmissions from an Parallel        Computing Artificial Intelligence-based Distributive Routing        Computer located within the TSFD Network Extender's dynamic        service area of captive Signal extenders 600 during a        catastrophic failure within the TSFD Network.        Operational Dynamic State Control by the TSFD Multi-Mode        Wireless Access Card (TSFD Wireless PC-DatCom) 500    -   1. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of a PC Home        Computer via the TSFD wireless ComDoc's peripheral interface        connections.    -   2. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of a cable        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   3. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of a PSTN/DSL        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless ComDoc's peripheral interface connections.    -   4. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of a LAN modem        for access by the TSFD wireless device to the Internet via the        TSFD wireless ComDoc's peripheral interface connections.    -   5. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of an External        Hard Drive for the retrieval of digital data via the TSFD        wireless ComDoc's peripheral interface connections.    -   6. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        ComDoc's peripheral interface connections.    -   7. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of an Infrared        Data Sensor via the TSFD wireless ComDoc's peripheral interface        connections.    -   8. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless ComDoc to exercise Dynamic State Control of an External        Video Camera via the TSFD wireless ComDoc's peripheral interface        connections.    -   9. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of a PC Home Computer via the TSFD        wireless ComDoc's peripheral interface connections.    -   10. A PCS, TDMA, CDMA, AMPS or GSM protocol wireless handset is        used to command a TSFD wireless ComDoc to exercise Dynamic State        Control of a cable modem for access by the PCS, TDMA, CDMA, AMPS        or GSM protocol wireless device to the Internet via the TSFD        wireless ComDoc's peripheral interface connections.    -   11. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of a PSTN/DSL modem for access by the PCS,        TDMA, CDMA, AMPS or GSM protocols wireless device to the        Internet via the TSFD wireless ComDoc's peripheral interface        connections.    -   12. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of a LAN modem for access by the PCS,        TDMA, CDMA, AMPS or GSM protocols wireless device to the        Internet via the TSFD wireless ComDoc's peripheral interface        connections.    -   13. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of an External Hard Drive for the        retrieval of digital data via the TSFD wireless ComDoc's        peripheral interface connections.    -   14. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of a CD/DVD Drive for the retrieval of        digital data via the TSFD wireless ComDoc's peripheral interface        connections.    -   15. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of an Infrared Data Sensor via the TSFD        wireless ComDoc's peripheral interface connections.    -   16. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless ComDoc to exercise        Dynamic State Control of an External Video Camera via the TSFD        wireless ComDoc's peripheral interface connections.    -   17. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of a PC Home        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   18. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of a cable        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   19. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of a        PSTN/DSL modem for access by the TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   20. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of a LAN        modem for access by the TSFD wireless device to the Internet via        the TSFD wireless X-DatCom's optional peripheral interface        connections.    -   21. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   22. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   23. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   24. A TSFD wireless PC-DatCom 500 is used to command a TSFD        wireless X-DatCom to exercise Dynamic State Control of an        External Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   25. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless X-DatCom to        exercise Dynamic State Control of a PC Home Computer via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   26. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols is used to command a TSFD wireless X-DatCom to        exercise Dynamic State Control of a cable modem for access by        the TSFD wireless handset operating in any one of the following        alternate protocols: PCS, TDMA, CDMA, AMPS or GSM protocols to        the Internet via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   27. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Dynamic State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by predetermined and defined software parameters        stored in the PNECP's internal Memory.    -   28. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor (PNECP); wherein the PNCEP is composed of PNE        Central Processors 830 a & 830 b comprising a whole and complete        PNE Central Processor system, to exercise Dynamic State Control        over the Subscriber Database, located on a website on the        Internet, containing all TSFD wireless handsets 300, TSFD        wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD        wireless X-DatComs 400 for activation, deactivation and billing        privileges by external instructions from a keypad, touch-active        video screen within the PNE housing or by such portable data        storage medium as will facilitate uploading new data        instructions when inserted in the PNECP's data drives.    -   29. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor to exercise Dynamic State Control over the        Subscriber Database, located on a website on the Internet,        containing all TSFD wireless handsets 300, TSFD wireless        PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD wireless        X-DatComs 400 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        TSFD Network.    -   30. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor to exercise Dynamic State Control over the        Subscriber Database, located on a website on the Internet,        containing all TSFD wireless handsets 300, TSFD wireless        PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD wireless        X-DatComs 400 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        PSTN, the Internet, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   31. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor to exercise Dynamic State Control over the        Subscriber Database, located on a website on the Internet,        containing all TSFD wireless handsets 300, TSFD wireless        PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD wireless        X-DatComs 400 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from the Parallel Computing Artificial        Intelligence-based Distributive Routing Computer located within        the Environmental Housing of the Network Extender.    -   32. A TSFD wireless PC-DatCom 500, via a secure access code, may        be used to instruct the Parallel-configured Network Extender        Central Processor to exercise Dynamic State Control over the        Subscriber Database, located on a website on the Internet,        containing all TSFD wireless handsets 300, TSFD wireless        PC-DatCom Cards 500, TSFD wireless ComDocs 900 and TSFD wireless        X-DatComs 400 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from an Parallel Computing Artificial        Intelligence-based Distributive Routing Computer located within        the TSFD Network Extender's dynamic service area of captive        Signal extenders 600 during a catastrophic failure within the        TSFD Network.    -   33. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor (PNECP);        wherein the PNCEP is composed of PNE Central Processors 830 a &        830 b comprising a whole and complete PNE Central Processor        system, to exercise Dynamic State Control over the Subscriber        Database, located on a website on the Internet, containing all        TSFD wireless handsets 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP's internal        Memory.    -   34. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor (PNECP);        wherein the PNCEP is composed of PNE Central Processors 830 a &        830 b comprising a whole and complete PNE Central Processor        system, to exercise Dynamic State Control over the Subscriber        Database, located on a website on the Internet, containing all        TSFD wireless handsets 300, TSFD wireless PC-DatCom Cards 500,        TSFD wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        NE housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP's data drives.    -   35. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the TSFD Network.    -   36. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the PSTN, the Internet,        direct copper connections using DS-1 connections, direct fiber        connections using OC-3 links, radio links with the DS-1        hardware, an Earth-Satellite ground station for direct two-way        communications with telecom satellites, the sending and        receiving of short haul, ultra-wide-band optical communications        via modulated Laser links.    -   37. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges from programming        instructions received by transmissions from the Parallel        Computing Artificial Intelligence-based Distributive Routing        Computer located within the Environmental Housing of the Network        Extender.    -   38. A TSFD wireless PC-DatCom 500 operating in any one of the        following alternate protocols: PCS, TDMA, CDMA, AMPS or GSM        protocols, via a secure access code, may be used to instruct the        Parallel-configured Network Extender Central Processor to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless PC-DatCom Cards 500, TSFD        wireless ComDocs 900 and TSFD wireless X-DatComs 400 for        activation, deactivation and billing privileges from programming        instructions received by transmissions from an Parallel        Computing Artificial Intelligence-based Distributive Routing        Computer located within the PNE's dynamic service area of        captive PSEs 600 during a catastrophic failure within the TSFD        Network.        V. Parallel-Configured TSFD Signal Extenders

Turning now to FIG. 20 and FIG. 21, FIG. 20 and FIG. 21 show blockdiagrams 150 and 160, in two complete sections; A and B respectively, ofa whole and complete (when combined during operations) PSE 600. Eachsection is a functional and independent Signal Extender that works inparallel independent of the other section such that each section isproviding a backup to the other section in case of failure of onesection. This configuration of the PSE is termed as theParallel-configuration, and the Signal Extender is termedParallel-configured Signal Extender. The PSE 600 serves as a signalrelay and frequency-translator between TSFD wireless handsets 300 andeither a PNE 800 or other TSFD wireless handsets 300. It receives blocksof data in the PCS low band and up-converts them for re-transmission inthe PCS high band, as discussed in relation to FIG. 4 through FIG. 7. Inthis relay process, the PSE 600 amplifies the radio frequency signals toincrease system range and coverage. The distinguishing feature of thePSE 600 is that it does not switch, process, or demodulate individualchannels or signals; it is limited in function to relaying blocks of RFspectrum. This functional simplicity is intended to yield lowinfrastructure cost. The only deviation from this design is to enableaccess to no more than four PSTN landlines as a routing backup during aPNE's catastrophic failure. Even this access is accomplished however,on-site through the wireless connectivity of four or more TSFD wirelessComDocs 900 attached to landlines. This approach eliminates structuraland physical design changes to the PSEs 600 and keeps costs low. TheParallel Computing Artificial Intelligence Distributive Routing Networkmerely makes suggestions for the PSE's 600 to follow: More landlines andTSFD wireless ComDocs 900 would raise the cost; however, never wouldthese additions ever approach the expense of altering the PSE 600design. This approach would also yield the cost benefits of modularexpansion should the need arise. Frequency translation is the primaryfunction of the PSE 600. Three such translator functions shall beprovided as follows:

Translator Type Relay Path Uplink TSFD wireless handset to PNE DownlinkPNE to Local TSFD wireless handset to TSFD wireless handset; eachtranslator is defined by the center frequency of the input spectrumblock, the bandwidth of the block, and an up-conversion offset. Theinput center frequency is a programmable parameter based on the licensedPCS block (A-F) and the microcell type (A1-3, B1-3, C1-3); see FIG. 3,FIG. 4 and FIG. 5. The bandwidth and up-conversion offset depend on thePCS block type (ABC or DEF). The three PSE 600 translator functionsoperate with the same bandwidth specifications. The bandwidth is fixedat 275 kHz for 5-MHz PCS block types (DEF) or at 825 for 15-MHz PCSblock types (ABC). Signals more than 50 kHz from the band edges arerejected by at least 20 dB relative to the band centers. Signals morethan 250 kHz from the band edges are rejected by at least 40 dB relativeto the band centers. The three PSE 600 translator functions operate withthe same frequency accuracy specifications. The input center frequencyis accurate to within 2 kHz and the up-conversation offset is accurateto within 500 Hz. The uplink translator 610 translates a block ofhandset signals to the PNE 800. The programmable up-conversion offset is82.5 MHz for 5-MHz PCS block types (DEF) or 87.5 MHz for 15-MHz PCSblock types (ABC). The programmable input center frequency is determinedaccording to the following expression:Fedge+Fguard+Bandwidth*(Extended+0.5)

where Fedge, Fguard, and Bandwidth are given in the table presented inFIG. 27, which shows PCS block parameters for PSE 600 frequencytranslators. The Table presented in FIG. 28 shows the values of extendedand local microcell type parameters for PSE 600 frequency translatorsused for the determination of center frequencies.

In a detailed illumination of the present invention, the internalcomponent number designators; i.e. (translator 620 for example) will bestated as 620 a & 620 b, as the Parallel-configured nature of the PSE'shardware and the internal operating software of FIG. 20 and FIG. 21 mustbe addressed together.

The downlink translator 620 a & 620 b translates a block of signals froma PNE 800 to the TSFD wireless handsets 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards 500, TSFD wireless ComDocs 900. Theprogrammable up-conversion offset is 77.5 MHz for 5-MHz PCS block types(DEF) or 72.5 MHz for 15-MHz PCS block types (ABC). The programmableinput center frequency is determined according to the followingexpression:Fmid+Fguard+Bandwidth*(Extended+0.5)

where Fmid, Fguard, and Bandwidth are given in FIG. 27, and values forExtended are given in FIG. 28. The local translator 630 a & 630 btranslates a block of TSFD wireless handset 300, TSFD wireless X-DatCom400, TSFD wireless PC-DatCom Card 500, TSFD wireless ComDoc 900 signalsto other TSFD wireless handsets 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500, TSFD wireless ComDocs 900. Theup-conversion offset is fixed to 80 MHz. The programmable input centerfrequency is determined according to the following expression:Fedge+Fguard+Bandwidth*(Local+0.5)

where Fedge, Fguard, and Bandwidth are given in FIG. 27, and the valuefor Local is given in FIG. 28. The omni antenna 640 a & 640 b is usedfor omni-directional PSE 600 communication with handsets 300 in amicrocell. The antenna gain is between 2 dBi and 6 dBi. The directionalantenna 650 a & 650 b is used for directional PSE 600 communication withthe fixed PNE site. The antenna gain is 15 dBi, with a front-to-backratio greater than 25 dB. Duplexers 645 a & 645 b, 655 a & 655 b areused to achieve isolation of the antenna signals between the transmitand receive frequency bands. This is required to allow full duplex,i.e., simultaneous transmit and receive, operation of the PSE 600. Theduplexers 645 a & 645 b, 655 a & 655 b provide transmit-receive (andreceive-transmit) isolation of at least 80 dB. An uplink low noiseamplifier (LNA) 660 a & 660 b is used to receive the TSFD wirelesshandset 300, TSFD wireless X-DatCom 400, TSFD wireless PC-DatCom Card500, TSFD wireless ComDoc 900 signals for the uplink translator 610 a &610 b and local translator 630 a & 630 b. The uplink LNA 660 a & 660 bprovides a received signal strength indicator (RSSI) 661 a & 661 boutput to the PSE 600 a & PSE 600 b controller 670 a & 670 b, indicatinga measure of the aggregate TSFD wireless handset 300, TSFD wirelessX-DatCom 400, TSFD wireless PC-DatCom Card 500, TSFD wireless ComDoc 900transmission activity in the microcell. An uplink power amplifier (PA)662 a &662 b is used to transmit the up-converted TSFD wireless handset300, TSFD wireless X-DatCom 400, TSFD wireless PC-DatCom Card 500, TSFDwireless ComDoc 900 signals to the PNE 800. The uplink PA 662 a & 662 bprovides an output level of at least 26 dBm across the entire PCS Highband (1930 to 1990 MHz). The uplink PA 662 a & 662 b is able to transmit66 signals at +4 dBm each simultaneously without damage. The uplink PA662 a & 662 b also provides means for enabling and disabling the output.A downlink low noise amplifier (LNA) 666 a & 666 b is used to receivePNE signals for the Downlink Translator 620 a & 620 b. A downlink poweramplifier (PA) 664 a 664 b is used to transmit the up-converted TSFDwireless handset 300, TSFD wireless X-DatCom 400, TSFD wirelessPC-DatCom Card 500, TSFD wireless ComDoc 900 signals to a PNE 800. Thedownlink PA 664 a & 664 b provides an output level of at least 48 dBmacross the entire PCS High band (1930 to 1990 MHz). The downlink PA 664is able to transmit 99 signals at +25 dBm each simultaneously withoutdamage. The downlink PA 664 a & 664 b also provides means for enablingand disabling the output.

PSE power amplifier gains of the three RF paths (uplink, downlink,local) are independently adjustable in 3 dB steps over a 60 dB rangefrom 37 to 97 dB. The gain adjustments are usually made manually duringinstallation based on the microcell size.

A control transceiver 680 a & 680 b is used to receive commands from thePNE 800 on the reference channel (RC) downlink, and to transmitacknowledgments and status reports on the RC uplink. The controller 670a & 670 b is used to program the PSE 600 configuration and monitorstatus for reporting. The controller 670 a & 670 b programs the PSE 600configuration, which consists of the Uplink, Downlink, and LocalTranslator frequencies, and the Uplink/Downlink PA output on/off state.The following information must be provided to the Controller:

Microcell Type (A1-3, B1-3, C1-3)

PCS Block (A-F)

Desired PA Output State (enabled or disabled)

The PSE Translator frequencies are configured based on the microcelltype and PCS band as described above. The controller 670 a & 670 baccepts remote commands from the PNE 800 via the control transceiver 680a & 680 b for programming the PSE 600 configuration. The controlleracknowledges the PNE commands. The controller also provides a local port672 a & 672 b such as an RS-232 for local programming of theconfiguration in the field from an external laptop computer and for allcommunications with the resident Parallel Computing ArtificialIntelligence Distributive Routing Network computer. Upon power-up, thecontroller 670 a & 670 b sets the PSE configuration to the lastconfiguration programmed. The controller periodically transmits statusreports to the PNE 800 via the control transceiver 680 a & 680 b. Thefollowing information is included in the status report:

Microcell type (A1-3, B1-3, C1-3)

PCS band (A-F)

PA output state (on or off)

Uplink LNA RSSI reading

Power draw reading

Power source state (external or battery backup)

An uninterruptible power supply (UPS) 690 a & 690 b is used to power thePSE 600 equipment and buffer it from the external power grid. In theevent of an external power grid outage, the UPS battery backupcapability is able to operate the PSE 600 for an extended period oftime.

Turning now to FIGS. 20 and 21; in alternate embodiment of the presentinvention, the TSFD Protocol PSE 600, an asynchronous communicationssystem package, is analogous to a greatly over simplified “mobileswitching center” or MSC in a cellular or PCS system. While an MSC maybe compared to a telephone CO (central office) or TO (toll office), thePNE 800 more closely compares to a PBX (Private Branch Exchange), whichconnects to a CO or TO. The PSE 600 enables the TSFD wirelesscommunication systems to function independently of an external networkwhen attached via an internal network, to a PNE 800. These TSFD wirelesscommunication systems, in which PSEs 600 and PNEs 800 are integralparts, are deployed as networks. These networks consist of one or morefixed PNE sites, with a number of fixed PSE 600 tower sites. The PNE 800may also be a fixed tower site. The networks are essentially theinfrastructure required to service TSFD wireless handsets 300, TSFDwireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFDwireless ComDocs 900 in a given geographical area. PSE sites serve asthe geographical “footprint” of this asynchronous wireless network,literally extending the range of the PNE 800, whose function moreclosely resembles a traditional PCS base station complex. In all butcatastrophic situations, the PNE 800 provides PSE wireless devicecliental a viable external network interface. With the aid of TSFDwireless ComDoc 900 technology, even the PNE 600 may interface withexternal networks, creating a unique disaster-backup system. Overseen byan advisory Parallel Computing Artificial Intelligence-basedDistributive Routing System 1300, PSE 600 can mimic a PNE 800 callcompletion duties during PNE disruptions or failures.

In an alternate embodiment of the present invention, FIGS. 20 and 21depict block diagrams (Section A and Section B) of a PSE 600. Thecombination of these two figures, FIGS. 20 and 21, represents a completeand whole PSE, a PSE 600. The PSE 600, Sections A and Sections B serveas wireless signal relays and frequency-translators between TSFDwireless handset 300 (or other wireless TSFD devices) and either a PNE800 or other TSFD wireless handset 300 (or other wireless TSFD devices).The PSE 600, as an asynchronous device, does not disassemble thewireless signals it receives from TSFD wireless devices. It merelychanges the whole signal to another frequency and sends it on,amplified. To be able to know on what channel to send the signal on, asuggestion is given by the PNE 800 as to the appropriate channel pair touse to complete the call. The PSE 600 also rebroadcasts the signalscreated to attempt to reach a particular phone or other TSFD wirelessdevice within the PSE 600 broadcast area. This is a rebroadcast of theCIC or Call Initiation Channel. The PNE 800 and the PSE 600 worktogether to locate a TSFD wireless device that is the potentialrecipient of the call being rebroadcast by the PSE 600. It would do nogood to attempt to reach a TSFD wireless device if that device waslocated in some other PSE 600 area or was out of service completely.Only after the recipient of the call acknowledges its presence andwilling PNEs 800 to receive the call, is the call setup completed by thePSE 600 and the calling device. The pattern of frequencies used andvacant are not the purview of the PSE 600 as no electronics exist withinthe PSE 600 system to determine status of the available spectrum.Organization and recommendations of which channel pair to utilize, isthe job of the PNE 800 or in the case of PNE 800 failure, the ParallelComputing Artificial Intelligence-based Distributive Call Routing System1300; the AI system. The distribution of the channels utilized by an PSE600 are to be determined by algorithms written to place calls closetogether, allocating unutilized groups of channel pairs for groupingtogether in the case of data transfer by CCAP or CCAP+. These SubProtocols of TSFD acquire clumps of channels and aggregate them togetherfor “Broadband” data transfer or for the TSFD sub-protocol, IDDT forlive direct digital streaming of video packeted signals. Then, havingcompleted the transfer, “snaps” back to a single voice/data channel todetermine transfer success (bit rate error verification). At no time isthe PSE 600 actually instrumental in decision making for such datatransfers. Oversight by the PNE 800 is the primary determinate ofchannel allocation or, in the event of catastrophic failure, the “AllPresent and Observing” Parallel Computing Artificial Intelligence-basedDistributive Routing System 1300.

An additional embodiment defines aspects of the present invention as:Communication with the PSE 600 can be accomplished in several ways:(though not limited to the presented examples)

-   -   1. Bi-directionally between PNE 800 and PSE 600 on the CIC (Call        Initiation Channel) via dedicated wireless link    -   2. Bi-directionally between PNE 800 and PSE 600 on the CIC (Call        Initiation Channel) via dedicated Fiber Optic link    -   3. Bi-directionally between PNE 800 and PSE 600 on the CIC (Call        Initiation Channel) via dedicated PSTN link    -   4. Bi-directionally between PNE 800 and PSE 600 on the CIC (Call        Initiation Channel) via dedicated Direct Optical link-modulated        bi-directional laser link    -   5. Bi-directionally between PNE 800 and PSE 600 on the CMC (Call        Maintenance Channel) via dedicated wireless link    -   6. Bi-directionally between PNE 800 and PSE 600 on the CMC (Call        Maintenance Channel) via dedicated Fiber Optic link    -   7. Bi-directionally between PNE 800 and PSE 600 via CMC (Call        Maintenance Channel) via dedicated PSTN link    -   8. Bi-directionally between PNE 800 and PSE 600 on the CMC (Call        Maintenance Channel) via dedicated Direct Optical link-modulated        bi-directional laser link    -   9. Bi-directionally between first PSE 600 and second PSE 600 on        the CIC (Call Initiation Channel) via dedicated Fiber Optic link    -   10. Bi-directionally between first PSE 600 and second PSE 600 on        the CIC (Call Initiation Channel) via dedicated PSTN link    -   11. Bi-directionally between first PSE 600 and second PSE 600 on        the CIC (Call Initiation Channel) via dedicated Direct Optical        link-modulated bi-directional laser link    -   12. Bi-directionally between first PSE 600 and second PSE 600 on        the CMC (Call Maintenance Channel) via dedicated wireless link    -   13. Bi-directionally between first PSE 600 and second PSE 600 on        the CMC (Call Maintenance Channel) via dedicated Fiber Optic        link    -   14. Bi-directionally between first PSE 600 and second PSE 600 on        the CMC (Call Maintenance Channel) via dedicated PSTN link    -   15. Bi-directionally between first PSE 600 and second PSE 600 on        the CMC (Call Maintenance Channel) via dedicated Direct Optical        link-modulated bi-directional laser link    -   16. Bi-directionally between a satellite ground station and PSE        600 on the CIC (Call Initiation Channel) via dedicated satellite        ground station link    -   17. Bi-directionally between satellite ground station and PSE        600 on the CMC (Call Maintenance Channel) via dedicated        satellite ground station link    -   18. Bi-directionally between the Parallel Computing Artificial        Intelligence-based Distributive Routing System 1300 and PSE 600        on the AI Interface    -   19. Bi-directionally between any TSFD wireless device (within        the broadcast area of the PSE 600) and the PSE 600 on the CIC        (Call Initiation Channel) via wireless TSFD signals    -   20. Bi-directionally between any TSFD wireless device (within        the broadcast area of the PSE 600) and the PSE 600 on the CMC        (Call Maintenance Channel) via wireless TSFD signals    -   21. Bi-directional data transfer and systems maintenance of the        PSE 600 via the PSE 600-PC interface

In yet another embodiment of the invention; regarding operations of TSFDwireless ComDoc 900, the TSFD wireless PC-DatCom Card 500 and/or theTSFD wireless X-DatCom 400 wireless TSFD devices and communications withthe PSE 600, all methods ascribed to operating TSFD wireless handset300, i.e.; CIC, CMC, etc. would be utilized. Unless otherwise stated,the TSFD wireless handset 300 illustrated in this embodiment alsoapplies to other TSFD wireless devices.

Example: TSFD wireless ComDoc 900 usage by TSFD wireless handset 300owner within a PSE 600 domain. It would still be necessary for the TSFDwireless handset 300 to access the PNE 800 “knowledge” of channel pairassignments via the CIC and CMC channels in order to place and completea call from the TSFD wireless handset 300 to the TSFD wireless ComDoc900 to an external network of choice (home PSTN line, Internet, HomeComputer attached to TSFD wireless ComDoc 900, etc.). However, seriousreduction in PNE 800 call routing assistance and complete elimination ofPNE 800 call interfaces to external networks (PSTN, Internet, etc.)would be achieved.

The PNE 800 receives blocks of data in the PCS low band and up-convertsthem for re-transmission in the PCS high band, as discussed in relationto FIG. 4 through FIG. 7 and FIGS. 26 and 27. In this relay process, thePSE 600 amplifies the radio frequency signals to increase system rangeand coverage. The distinguishing feature of the PSE 600 is that it doesnot switch, process, or demodulate individual channels or signals; it islimited in function to relaying blocks of RF spectrum. This functionalsimplicity is intended to yield low infrastructure cost. Frequencytranslation is the primary function of the PSE 600. Three suchtranslator functions shall be provided as follows:

-   -   Translator Type Relay Path    -   Uplink TSFD wireless handset 300 to PNE 800    -   Downlink PNE 800 to TSFD wireless handset 300    -   Local TSFD wireless handset 300 to TSFD wireless handset 300        Each translator is defined by the center frequency of the input        spectrum block, the bandwidth of the block, and an up-conversion        offset. The input center frequency is a programmable parameter        based on the licensed PCS block (A-F) and the microcell type        (A1-3, B1-3, C1-3). The bandwidth and up-conversion offset        depend on the PCS block type (ABC or DEF). The three PSE 600        translator functions operate with the same bandwidth        specifications. The 3-dB bandwidths are fixed at 275 kHz for        5-MHz PCS block types (DEF) or at 825 kHz for 15-MHz PCS block        types (ABC). Signals more than 50 kHz from the band edges are        rejected by at least 20 dB relative to the band centers. Signals        more than 250 kHz from the band edges are rejected by at least        40 dB relative to the band centers. The three PSE 600 translator        functions operate with the same frequency accuracy        specifications. The input center frequency is accurate to within        2 kHz and the up-conversation offset is accurate to within 500        Hz. The uplink translator translates a block of TSFD wireless        handset 300 signals to the PNE 800. The programmable        up-conversion offset is 82.5 MHz for 5-MHz PCS block types (DEF)        or 87.5 MHz for 15-MHz PCS block types (ABC). The programmable        input center frequency is determined according to the following        expression:        Fedge+Fguard+Bandwidth(Extended+0.5)

where Fedge, Fguard, and Bandwidth are given in the table presented inFIG. 29, which shows PCS block parameters for PSE 600 frequencytranslators. FIG. 30 shows the values of extended and local microcelltype parameters for PSE 600 frequency translators used for thedetermination of center frequencies. The downlink translator translatesa block of signals from a PNE 800 to the TSFD wireless handset 300. Theprogrammable up-conversion offset is 77.5 MHz for 5-MHz PCS block types(DEF) or 72.5 MHz for 15-MHz PCS block types (ABC). The programmableinput center frequency is determined according to the followingexpression:Fmid+Fguard+Bandwidth(Extended+0.5)

where Fmid, Fguard, and Bandwidth are given in FIG. 29, and values forExtended are given in [FIG. 30]. The local translator translates a blockof TSFD wireless handset 300 signals to other TSFD wireless handset 300.The up-conversion offset is fixed to 80 MHz. The programmable inputcenter frequency is determined according to the following expression:Fedge+Fguard+Bandwidth(Local+0.5)

where Fedge, Fguard, and Bandwidth are given in FIG. 29, and the valuefor Local is given in FIG. 30. The omni antenna is used foromni-directional PSE 600 communication with TSFD wireless handset 300 ina microcell. The antenna gain is between 2 dBi and 6 dBi. Thedirectional antenna is used for directional PSEcommunication with thefixed PNE site. The antenna gain is 15 dBi, with a front-to-back ratiogreater than 25 dB. The Optical Cable Interface utilizes a RFTransmission Translator (not shown) to interface an optical cable withthe RF Duplexer section of the PSE 600 should there be no means ofachieving a radio (antenna) PSE 600 to PSE 600 link. A similar OpticalCable interface method also enables PSE 600 to PNE 800 linkage shouldradio linkage fail. Internet linkage is also provided for activeinterface through the AI computer (not shown). This method would allowInternet telephony

In a further embodiment of the present invention, duplexers are used toachieve isolation of the antenna signals between the transmit andreceive frequency bands. This is required to allow full duplex, i.e.,simultaneous transmit and receive, operation of the PSE 600. Theduplexers provide transmit-receive (and receive-transmit) isolation ofat least 80 dB. An uplink low noise amplifier (LNA) is used to receivethe TSFD wireless handset signals for the uplink translator and localtranslator. The uplink LNA provides a received signal strength indicator(RSSI) output to the PSE controller, indicating a measure of theaggregate TSFD wireless handset transmission activity in the microcell.An uplink power amplifier (PA) is used to transmit the up-converted TSFDwireless handset signals to the PNE 800. The uplink PA provides anoutput level of at least 26 dBm across the entire PCS High band (1930 to1990 MHz). The uplink PA is able to transmit 66 signals at +4 dBm eachsimultaneously without damage. The uplink PA also provides means forenabling and disabling the output. A downlink low noise amplifier (LNA)is used to receive PNE signals for the Downlink Translator. A downlinkpower amplifier (PA) is used to transmit the up-converted TSFD wirelesshandset signals to a PNE 800. The downlink PA provides an output levelof at least 48 dBm across the entire PCS High band (1930 to 1990 MHz).The downlink PA is able to transmit 99 signals at +25 dBm eachsimultaneously without damage. The downlink PA also provides means forenabling and disabling the output. The PSE power amplifier gains of thethree RF paths (uplink, downlink, local) are independently adjustable in3 dB steps over a 60 dB range from 37 to 97 dB. The gain adjustments areusually made manually during installation based on the microcell size.

A control transceiver is used to receive commands from the PNE 800 onthe reference channel (RC) downlink, and to transmit acknowledgments andstatus reports on the RC uplink. The controller is used to program thePSE 600 configuration and monitor status for reporting. The controllerprograms the PSE 600 configuration, which consists of the Uplink,Downlink, and Local Translator frequencies, and the Uplink/Downlink PAoutput on/off state. The following information must be provided to theController:

-   -   Microcell Type (A1-3, B1-3, C1-3)    -   PCS Block (A-F)    -   Desired PA Output State (enabled or disabled)

The PSE Translator frequencies; FIG. 28, are configured based on themicrocell type and PCS band as described above. The controller acceptsremote commands from the PNE 800 via the control transceiver forprogramming the PSE 600 configuration. The controller acknowledges thePNE 800 commands. The controller also provides a local port such as anRS-232 for local programming of the configuration in the field from anexternal laptop computer. Upon power-up, the controller sets the PSE 600configuration to the last configuration programmed. The controllerperiodically transmits status reports to the PNE 800 via the controltransceiver. The following information is included (but not limited tothis example) in the status report:

-   -   Microcell type (A1-3, B1-3, C1-3)    -   PCS band (A-F)    -   PA output state (on or off)    -   Uplink LNA RSSI reading    -   Power draw reading    -   Power source state (external or battery backup)

An uninterruptible power supply 880 (UPS) is used to power the PSE 600equipment and buffer it from the external power grid. In the event of anexternal power grid outage, the UPS battery backup capability is able tooperate the PSE 600 for an extended period of time.

Further disclosure of the operational theory of the PSE 600 is presentedby illuminating characteristics of system protocols, circuits andrelated physics of TSFD signal propagation, which are listed below:

-   -   1. Being an asynchronous device; i.e., a device that does not        operate in a “Lock Step” fashion with other wireless devices.        Serious savings in equipment costs can be garnered from the        elimination of timing, multiplexing, modulation and        demodulation, circuits within the PSE 600    -   2. Allowing each signal set (signals generated on one set of        channel pairs) to merely be translated on to another set of        channel pairs, amplified and rebroadcast, reduces PSE 600        circuit complexity; cost. A PSE 600 mimics a CB radio repeater        as that system is akin to an “asynchronous” system.

Asynchronous functionality provides for the ability to cascade PSE 600(sending a signal from one PSE 600 to another PSE 600 to another PSE 600to a waiting TSFD wireless handset 300) signals over very long distancesbefore the signal reaches a latency that is detectable (orobjectionably) to a human's ear. This time maximum delay generated byrepeating a signal over and over has been calculated to be about 80milliseconds. That time delay translates into a PSE 600 to PSE 600distance of almost 1,000 miles between starting TSFD wireless handset300 and receiving TSFD wireless handset 300. The very best limit of astandard PCS base station utilizing a repeater is a theoretical limit of27 miles. This number is based upon the knowledge that a wireless signalfrom one TSFD wireless handset 300 to another (with a base station and arepeater in between) must stay synchronized with both beginning TSFDwireless handset 300, the base station, the repeater and the receivingTSFD wireless handset 300. Measuring the speed of light as the constantfor wireless signal transmission, 27 miles is the maximum distance a PCSsignal may travel back and forth before loosing the synchronous “lock”on the signal required by the base station. No such limit exists withthe PSE 600 TSFD Protocol as the beginning and ending wireless TSFDdevices set the “lock” arrangements on the transmissions without regardto multiple PSE 600 re-transmissions. Were it not for an annoying timedelay between sending and receiving TSFD signals between TSFD wirelesshandset 300 (Example: television reporters overseas demonstrate over 800millisecond delays before responding to a question posed by a USreporter; due to this distance imposed delay), a TSFD signal couldeffectively be sent from the earth to the moon and back again with adelay of about 5½ seconds (5,000 milliseconds). Still, no synchronous“lock” would be required between an earth and a lunar handset.

Turning now to signal propagation: the PSE 600 demonstrates a simple,un-multiplexed signal transmission methodology wherein a signal is sentcompressed 50%, received and decompressed and played back. While thedecompression is occurring a signal on another channel is sent back tothe sender of the 50% signal; also compressed 50%. Since this happenscontinuously (send, receive, send, receive) but never allowing both tosend at the same time; the illusion of “Full Duplex” is created. Thismethod, Time Shared Full Duplex or TSFD, eliminates the need forsynchronous operations between TSFD wireless devices and a tower andexpensive and complicated channel filtration to avoid crosstalk. Batterylife is extended as transmissions are only on a 50% duty cycle.Excessive cranial exposure to microwave radiation is vastly reduced.Transmission of a clean, un-multiplexed signal allows for further signalpropagation with less possibilities of failure due to an excessive biterror rate, interference by obstructions, multi-path, adverseatmospheric conditions, or excessive pressure on the electromagneticspectrum due to broadcast overload. The TSFD propagation methodology hasbeen likened to a rifle firing a projectile where as standard PCSpropagation is analogous to a blast of bird shot from a shotgun. Rifleprojectiles go further, shotgun projectiles drop quickly and lose power.However, on short distances, shotguns have their uses and theirprojectiles can be effective, as is WiFi for example.

The simple electronic package making up the PSE 600, does not requireair conditioning or heating. Deviation in signal frequency generallyattributed to temperature, is corrected by “locking” on to the GPSsatellite system and correcting signal drift on a continuous, closedloop basis.

The number of effective channel pair within a PSE 600 broadcastcapabilities is not fixed; i.e., it is a function of design notprotocol. The TSFD system may be manufactured to operate on anyfrequency bandwidth between 50 megahertz and 5 gigahertz. Frequenciesbelow 50 MHz do not have the capacity to carry enough calls to beeconomically effective. Distance is however a tremendous advantagebetween 50 and 450 MHz. Above 5 GHz, atmospheric limitations are theprimary constraining factor. Distance also suffers as the signal is aline of sight, no forgiveness 800, short-haul functionality. Callcarrying capacity is however, extremely efficient. Wherever the TSFD PSE600 is scheduled to be deployed, licensing and frequency availabilityhead the list. Call carrying capacity must be balanced with the otherfactors previously listed. Within the USA, the TSFD system is limited tothe Blocked PCS spectrum and licensing arrangements. However, the TSFDsystem is not limited by spectrum frequency and must not be assumed tobe constrained to the PCS Spectrum Block of the USA.

It must be noted that no signals are generated by the PSE 600 when thereare no wireless calls being received and re-transmitted. Therefore, aTSFD wireless device that “wishes” to make a call and initiates thebeginning procedures to do so has no predetermined set of channelsemanating from the PSE 600 from which to choose. The TSFD wirelessdevice, via the CIC and CMC channels, is given the suggestion of afrequency pair from which to choose. This pair is “created” by softwarewithin the device which reviews a library internally and references thestored frequencies to a GPS signal supplying a known value. Should anydifferences between the device's stored frequencies ascribed to aparticular channel set and that of the referenced GPS adjustment factorbe indicated, the device makes the necessary changes and commencesbroadcasting on the “assigned” channel pair. After frequency translationand amplification by the PSE 600, a similar evaluation is made by thereceiving TSFD wireless device to establish a solid link with the PSE600. The receiving device received a frequency channel pairrecommendation by the PNE 800 through the CIC and the CMC; relayed bythe PSE 600. Once all parties accepted the suggestions and reported thisacceptance to the PNE 800 via the PSE 600, the call initiation could becompleted and conversation could begin. Still, the only frequenciesemanating from the PSE 600 would be the first and second channel pairsutilized by the “connected” wireless devices; via the PSE 600. Thisyields low pressure on the electromagnetic spectrum and superiorperformance by the PSE 600 and the TSFD wireless devices operatingwithin this “block” of frequencies assigned to their service. It lessensthe chances of other adverse factors such as sunspots, rain, snow,sleet, dust, etc. causing disruptions of calls. It also improves signalclarity and reduces bit error rates overall.

PSE 600 may use whatever style of antenna deemed effective; i.e.,directional, omni-directional, vertically polarized, horizontallypolarized or any combination there of. Pre-manufactured “Smart” antennasare also allowed should such designs be deemed of value.

PSE 600 should have such internal and external security systems as tomake them more likely to function for long periods of time. Security isdefined as: any system both physical or software based, which securesthe operation and functionality of the TSFD PSE 600 from unauthorizedaccess or use. Cameras on a PSE 600 site should be used as well asmotion sensors, locks, fences, signs, monitoring of noise within the PSE600 electronics package, excessive heat detection (cutting torch),software-based detection of TSFD systems intrusion by hackers.

The TSFD wireless communication system is for the transmission of voiceand data signals, enabling the establishing of a local communicationpath for transmitting and receiving signals between a local TSFDwireless handset 300 and a local communication docking bay within a samemicrocell via a PSE 600; establishing an extended communication path fortransmitting and receiving signals between an extended TSFD wirelesshandset 300 and an extended communication docking bay located withindifferent microcells positioned within a same macrocell via PSE 600 anda Parallel-configured Network Extender 800; establishing a distantcommunication path for transmitting and receiving signals between adistant TSFD wireless handset 300 and a distant communication dockingbay located within different microcells positioned within differentmacrocells via PSE 600 and PNE 800; and asynchronously transmitting andreceiving half-duplex signals over the communication paths using pairsof assigned communication path frequencies stabilized by a GPS-basedfrequency reference source.

This TSFD method enables the step of establishing a local communicationpath comprising the transmitting of signals from a local TSFD wirelesshandset 300 and a communication docking bay to a PSE 600; receiving andre-transmitting signals by the PSE 600 to the local TSFD wirelesshandset 300 and the communication docking bay; and receiving signalsfrom the PSE 600 by a local TSFD wireless handset 300 and acommunication docking bay.

The TSFD method also describes that half of the signals transmitted by aPSE 600 in a microcell are received by the TSFD wireless handset 300 anddocking bays in the microcell in a high radio frequency band and half ofthe signals transmitted by the PSE 600 in a macrocell are received a PNE800 in the macrocell in a high radio frequency band.

The TSFD method also shows the external network may be selected from thegroup consisting of a Public Switch Telephone Network 19, a fiber opticcommunication link, a coaxial cable, a public TCP/IP network, and asatellite communication link.

The TSFD method also shows that half of the signals received by a PSE600 in a microcell are transmitted by TSFD wireless handset 300 andcommunication docking bays in the microcell in a low radio frequencyband and half of the signals received by the PSE 600 in a microcell aretransmitted by a PNE 800 in the macrocell in a low radio frequency band.

If examined further, the TSFD method shows that half of the signalstransmitted by a PSE 600 in a microcell are received by the TSFDwireless handset 300 and communication docking bays in the microcell ina high radio frequency band and half of the signals transmitted by thePSE 600 in a microcell are received by a PNE 800 in the macrocell in ahigh radio frequency band.

This method, known as the Time Shared Full Duplex Protocol (TSFD), isthe primary mode of operation comprising the TSFD wireless frequencyprotocol.

All TSFD wireless devices are multi-mode in functionality and as such,may select from any of the following group of wireless protocolsconsisting of (but not limited to) AMPS, D-AMPS, IS-95, IS-136, and GSM1for their secondary mode of operation.

The TSFD method or protocol allows for the controlling an operationalstate of the wireless communication system by transmitting anoperational state command to a PNE 800.

The TSFD Protocol allows the selection of external networks by a PNE 800from the group consisting of a Public Switch Telephone Network (PSTN)19, a fiber optic communication link, a coaxial cable, a public TCP/IPnetwork, a Microwave link, a dedicated optical link, and a satellitecommunication link.

The TSFD network provides for the internal transmitting and receiving ofinformation over a call maintenance channel for call completion, callrequest, 911 position report, call handoff frequency, call waitingnotification, voice message notification, text message notification, andacknowledgement.

The TSFD network establishes that a microcell will comprise ageographical area containing one or more TSFD wireless handset 300carried by mobile users, communication docking bays, and a PNE 600; anda macrocell comprise a geographical area containing between one andtwenty one microcells, and a PNE 800.

The TSFD system is particularly suitable for operation in rural areaswhere population density is low and wireless coverage is either notcurrently available or not adequately serviced. The system is suitablefor operation in the United States using the PCS spectrum (1850 or theWireless Communications Service (WCS) spectrum at 2320 2360 MHz that arelicensed by the Federal Communications Commission (FCC) or any othersuch frequency as may be determined suitable above 50 megahertz and lessthan 5 gigahertz. The TSFD wireless handset 300 and the TSFD wirelessComDoc 900 incorporate a modular multi-mode capability to extend thewireless service area with a potential variety of standard wirelessformats and bands, such as AMPS, D-AMPS, IS-95, IS-136, and GSM1. Thisis an important feature because widespread deployment of a new wirelessservice takes appreciable time, and there are many other wirelessstandards from which to choose since these new customers may alsoventure into standard PCS or cellular markets. Besides the US ruralmarket, other applications for present invention include emergingnations, especially those that presently have limited or no telephoneservice, and those communities or groups that require a stand alonewireless communication network that can be quickly and cost-effectivelydeployed.

There are many permutations and combinations of signal paths that arepossible in the present system. For example, TSFD wireless handset 300or TSFD wireless ComDoc 900 in the same microcell may communicate withone another via a PSE 600. TSFD wireless handset 300 or TSFD wirelessComDoc 900 in different microcells but within the dame macrocell maycommunicate with on another via PSE 600 and PNE 800. Since computers andconventional telephones may be connected to a TSFD wireless ComDoc 900,these devices may also communicate with other devices connected to thewireless network. Two or more computers may connect to one another viathe wireless network at a minimum data rate of 56 kbps using ContiguousChannel Acquisition Protocol, or up to a maximum data rate of 250 kbpsusing Contiguous Channel Acquisition Protocol Plus; FIG. 10, via asingle PSE 600. Similarly, since a laptop computer may be connected to aTSFD wireless handset 300, it may also communicate with other devicesconnected to the wireless network. Since a TSFD wireless ComDoc 900 mayalso be connected to a PSTN, cable or other communication networkmedium, a TSFD wireless handset 300 may communicate directly orindirectly via a PSE 600 to a TSFD wireless ComDoc 900 to a PSTN networkor cable network. A TSFD wireless ComDoc 900 may also communicate via aPSE 600 and a PNE 800 to a PSTN network.

Within the TSFD system, the antenna pattern between the PSE 600 and TSFDwireless handset 300 is generally omni-directional since the TSFDwireless handset 300 are typically mobile throughout the surroundingarea of the PSE 600. The antenna pattern between a TSFD wireless ComDoc900 and a PSE 600 is also generally omni-directional, since the TSFDwireless ComDoc 900 operates on the same designated frequencies as theTSFD wireless handset 300 and may be moved to a new location at anytime.In contrast, the antenna pattern between the PSE 600 and PNE 800 can bea narrow beam since the PSE 600 and PNE 800 sites are both at fixedlocations. The PSE 600 is analogous to a simplified “base transceiverstation” or BTS in a cellular or PCS system. A key point tosimplification is that the PSE 600 does not switch, process, ordemodulate individual channels or calls. It is limited in function torelaying blocks of RF spectrum. The PNE 800 is a central hub and switchfor interconnecting calls both within the system and to externalnetworks such as the PSTN. The PNE 800 assists TSFD wireless handset 300in establishing calls, assists in interconnecting TSFD wireless ComDoc900 and TSFD wireless handset 300 within the TSFD service area, assistsTSFD wireless ComDoc 900 to TSFD wireless ComDoc 900 data links withinthe TSFD service area, manages the voice/data and signaling channels,and effectively connects calls for PSEs 600 that are connected to thePNE 800. Since the PNE 800 must be in radio line-of-sight with the PSEs600 that it services, its location site may be critical in systemdeployment. A hardware connection between the PSE 600 and the PNE 800may substitute for difficult line-of-site deployments. The PNE 800 isanalogous to a simplified “mobile switching center” or MSC in a cellularor PCS system. While an MSC may be compared to a telephone CO (centraloffice) or TO (toll office), the PNE 800 more closely compares to a PBX(Private Branch Exchange), which connects to a CO or TO. The PNE 800enables the wireless communication systems to function independently ofan external network.

Within the PSE 600, each translator is defined by the center frequencyof the input spectrum block, the bandwidth of the block, and anup-conversion offset. The input center frequency is a programmableparameter based on the licensed PCS block (A-F) and the microcell type(A1-3, B1-3, C1-3). The bandwidth and up-conversion offset depend on thePCS block type (ABC or DEF). The three PSE 600 translator functionsoperate with the same bandwidth specifications. The 3 bandwidth is fixedat 275 kHz for 5-MHz PCS block types (DEF) or at 825 for 15-MHz PCSblock types (ABC). Signals more than 50 kHz from the band edges arerejected by at least 20 dB relative to the band centers. Signals morethan 250 kHz from the band edges are rejected by at least 40 dB relativeto the band centers. The three PSE 600 translator functions operate withthe same frequency accuracy specifications. The input center frequencyis accurate to within 2 kHz and the up-conversation offset is accurateto within 500 Hz. The uplink translator translates a block of TSFDwireless handset 300 signals to the PNE 800. The programmableup-conversion offset is 82.5 MHz for 5-MHz PCS block types (DEF) or 87.5MHz for 15-MHz PCS block types (ABC). The programmable input centerfrequency is determined according to the following expression:F.sub.edge+F.sub.guard+Bandwidth (Extended+0.5) where F.sub.edge,F.sub.guard, and Bandwidth are given in FIG. 29, which shows PCS blockparameters for PSE 600 frequency translators.

In FIG. 29 F.sub.edge F.sub.mid F.sub.guard Bandwidth PCS Block (MHz)(MHz) (MHz) (MHz) A 1850 1857.5 0.012500 0.825000 B 1870 1877.5 C 18951902.5 D 1865 1867.5 0.037500 0.275000 E 1885 1887.5 F 1890 1892.5

FIG. 30 shows the values of extended and local microcell type parametersfor PSE 600 frequency translators used for the determination of centerfrequencies.

Microcell Type Extended Local A1 0 1 B1 1 2 C1 2 0 A2 3 4 B2 4 5 C2 5 3A3 6 7 B3 7 8 C3 8 6

The downlink translator translates a block of signals from a PNE 800 tothe TSFD wireless handset 300. The programmable up-conversion offset is77.5 MHz for 5-MHz PCS block types (DEF) or 72.5 MHz for 15-MHz PCSblock types (ABC). The programmable input center frequency is determinedaccording to the following expression:F.sub.mid+F.sub.guard+Bandwidth(Extended+0.5)

where F.sub.mid, F.sub.guard, and Bandwidth are given in FIG. 29, andvalues for Extended are given in FIG. 30. The local translatortranslates a block of TSFD wireless handset 300 signals to other TSFDwireless handset 300.

The up-conversion offset is fixed to 80 MHz. The programmable inputcenter frequency is determined according to the following expression:F.sub.edge+F.sub.guard+Bandwidth(Local+0.5

where F.sub.edge, F.sub.guard, and Bandwidth are given in FIG. 29, andthe value for Local is given in FIG. 30. The omni antenna is used foromni-directional PSE 600 communication with TSFD wireless handset 300 ina microcell. The antenna gain is between 2 dBi and 6 dBi. Thedirectional antenna is used for directional PSE 600 communication withthe fixed PNE 800 site. The antenna gain is 15 dBi, with a front-to-backratio greater than 25 dB. Duplexers, are used to achieve isolation ofthe antenna signals between the transmit and receive frequency bands.This is required to allow full duplex, i.e., simultaneous transmit andreceive, operation of the PSE 600. The duplexers, providetransmit-receive (and receive-transmit) isolation of at least 80 dB. Anuplink low noise amplifier (LNA) is used to receive the TSFD wirelesshandset 300 signals for the uplink translator and local translator. Theuplink LNA provides a received signal strength indicator (RSSI) outputto the PSE 600 controller, indicating a measure of the aggregate TSFDwireless handset 300 transmission activity in the microcell. An uplinkpower amplifier (PA) is used to transmit the up-converted TSFD wirelesshandset 300 signals to the PNE 800. The uplink PA provides an outputlevel of at least 26 dBm across the entire PCS High band (1930 to 1990MHz). The uplink PA is able to transmit 66 signals at +4 dBm eachsimultaneously without damage. The uplink PA also provides means forenabling and disabling the output. A downlink low noise amplifier (LNA)is used to receive PNE 800 signals for the Downlink Translator. Adownlink power amplifier (PA) is used to transmit the up-converted TSFDwireless handset 300 signals to a PNE 800. The downlink PA provides anoutput level of at least 48 dBm across the entire PCS High band (1930 to1990 MHz). The downlink PA is able to transmit 99 signals at +25 dBmeach simultaneously without damage. The downlink PA also provides meansfor enabling and disabling the output.

The PSE 600 power amplifier gains of the three RF paths (uplink,downlink, local) are independently adjustable in 3 dB steps over a 60 dBrange from 37 to 97 dB. The gain adjustments are usually made manuallyduring installation based on the microcell size.

A control transceiver is used to receive commands from the PNE 800 onthe reference channel (RC) downlink, and to transmit acknowledgments andstatus reports on the RC uplink. The controller is used to program thePSE 600 configuration and monitor status for reporting. The controllerprograms the PSE 600 configuration, which consists of the Uplink,Downlink, and Local Translator frequencies, and the Uplink/Downlink PAoutput on/off state. The following information must be provided to theController:

Microcell Type (A1-3, B1-3, C1-3)

PCS Block (A-F)

Desired PA Output State (enabled or disabled)

The PSE 600 Translator frequencies are configured based on the microcelltype and PCS band as described above. The controller accepts remotecommands from the PNE 800 via the control transceiver for programmingthe PSE 600 configuration. The controller acknowledges the PNE 800commands. The controller also provides a local port such as an RS-232for local programming of the configuration in the field from an externallaptop computer. Upon power-up, the controller sets the PSE 600configuration to the last configuration programmed. The controllerperiodically transmits status reports to the PNE 800 via the controltransceiver. The following information is included in the status report:

a. Microcell type (A1-3, B1-3, C1-3)

b. PCS band (A-F)

c. PA output state (on or off)

d. Uplink LNA RSSI reading

e. Power draw reading

f. Power source state (external or battery backup)

An uninterruptible power supply (UPS) is used to power the PSE 600equipment and buffer it from the external power grid. In the event of anexternal power grid outage, the UPS battery backup capability is able tooperate the PSE 600 for an extended period of time.

There is no formal or actual connection between the PSE 600 and thePSTN. The connection is accomplished by providing the PSE 600 its ownset of TSFD wireless ComDocs 900.

VI. Parallel-Configures TSFD Network Extenders

Turning now to FIG. 22 and FIG. 23, FIG. 22 and FIG. 23 shows a PNE 800where FIG. 22 represents Section A and FIG. 23 represents Section B;both Figures combined constituting a complete TSFD wireless Anchoredcomponent. Each section is a functional and independent Network Extenderthat works in parallel independent of the other section such that eachsection is providing a backup to the other section in case of failure ofone section. This configuration of the PNE is termed as theParallel-configuration, and the Network Extender is termedParallel-configured Network Extender.

An alternative embodiment of the invention; the TSFD Protocol PNE 800,an asynchronous communications system package is analogous to asimplified “mobile switching center” or MSC in a cellular or PCS system.While an MSC may be compared to a telephone CO (central office) or TO(toll office), the PNE 800 more closely compares to a PBX (PrivateBranch Exchange), which connects to a CO or TO. The PNE 800 enables theTSFD wireless communication systems to function independently of anexternal network.

These TSFD wireless communication systems, in which PNE 800 are anintegral part, are deployed as networks. These networks consist of oneor more fixed PNE sites and a number of fixed, tower sites known as PSEsites, associated with each PNE 800. The PNE 800 may also be a fixedtower site. The networks are essentially the infrastructure required toservice TSFD wireless handset 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900 in a givengeographical area. A network that includes multiple PNEs 800 mustsupport the exchange of digital voice, signaling, data, remote systemmonitoring, sharing of system databases, voice-over IP, remote dataretrieval, and remote control of instrumentation between PNE 800 in thenetwork. These networks are isolated from external networks unless oneor more PNE 800 are connected to a Public Switched Telephone Network(PSTN) 19, the Internet 15 (for Internet 15 services or voice-over-IP),to a dedicated fiber optic network, or other such external networks asmay be required. With PSTN 19 access, these internal networks cansupport calls between isolated internal networks, as well as incomingand outgoing calls with other phones in the PSTN 19. Internet 15 accessvia Internet 15 service providers (ISPs) enable remote systemmonitoring, data entry, sharing of system databases, voice-over IP,remote data retrieval, and remote control of external devices whileconnection to a dedicated fiber optic cable provides a dedicated fiberoptic network between PNEs 800 and or PSEs 600. The TSFD wirelesscommunication system is comprised of macrocells, where each macrocellincludes a PNE 800 communicating with a number of PSEs 600 thatcommunicate with a number of TSFD wireless handsets 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 or TSFD wirelessComDocs 900. The PNEs 800 are connected together by communicationbackbones. PNEs 800 may also connect to a PSTN 19 via a trunk line to acentral switching office. PNEs 800 may also connect to the Internet 15via a connection to an Internet 15 service provider. Additional exoticexternal network interfaces may be provided: Satellite ground stations,microwave networks, Ham radio transceivers (in extreme emergencies), andline of sight optical communications links. Therefore, these wirelesscommunication systems may also be interconnected through moretraditional means: the Internet 15, a PSTN 19 connection, dedicatedcopper cables, dedicated fiber optic cables, dedicated microwave links,or a TSFD wireless ComDoc-to-PSTN 19 interface. The PNE 800 is thecentral routing point for a macrocell, and the external interface toother macrocells, a PSTN 19 and the Internet 15. The PNE 800incorporates a Global Positioning System (GPS)-based reference sourcefor use in stabilizing the local oscillators in wireless communicationsystem transceivers.

In a detailed illumination of the present invention, the internalcomponent number designators; i.e. (translator 820 a & 820 b forexample) will be stated as 820 a & 820 b, as the Parallel-configurednature of the PNE's hardware and the internal operating software of FIG.22 AND FIG. 23 must be addressed together; as the PNE is only completewith each Section functioning together.

The reference output frequency is 10 MHz at the nominal accuracyavailable from the GPS. The GRP reference source 810 a & 810 ba & 810 a& 810 bb provides a reference frequency used by the PNE 800 transceiversand transmitted to the PSEs 600, TSFD wireless handset 300, or TSFDwireless X-DatComs 400 via a Reference Channel downlink. In addition,the GRP reference source 810 a & 810 ba & 810 a & 810 bb provides dateand time information for the macrocell, which is broadcast on the RC(Reference Channel) downlink. The GRP reference source 810 a & 810 bincludes the GPS antenna and a backup reference source suitable tomaintain frequency tolerance of RF (Radio Frequency) communicationchannels. The backup source is automatically selected in the event ofGPS signal loss or receiver failure. A Reference Distributor 812 a & 812b provides amplification and fan-out, as necessary, to feed the GPSreference signal to the microcell transceiver banks 820 a & 820 b. ThePNE 800 uses directional antennas for communication with the fixed PSE600 sites. The antenna gain is at least 15 dBi with a front-to-backratio greater than 25 dB. There is one dedicated antenna for each PSE600 supported by the PNE 800. Each PNE's 800 directional antenna for amicrocell is connected to a microcell transceiver bank within the PNE800. Each microcell transceiver bank contains a configurable number oftransceivers for processing the extended path and signaling channels forthe associated microcell. A microcell radio processor is containedwithin each macrocell receiver bank. Microcell servers connect to radioswithin the microcell transceiver banks 820 a & 820 b (inside the PNE800) to perform control functions associated with a single microcell.The microcell server 822 a & 822 b communicates with the PNE centralprocessor to route and manage calls that connect outside of themicrocell. The PNE central processor is able to direct the microcellserver 822 a & 822 b to promote a call from local mode to assisted mode,change frequency, or perform a handoff. The microcell server 822 a & 822b coordinate control of calls on its microcell, including performingcontrol operations of radios within its microcell transceiver banks 820a & 820 b. The microcell servers 822 a & 822 b accumulate the data forthe reference channel and feed it to the radio generating the RC. Theyalso process requests on the CIC (Call Initiation Channel) and CMC (CallMaintenance Channel) and coordinate the required actions with the radiosin its bank and the PNE central processor. A microcell server 822 a &822 b may handle multiple transceiver banks. Each microcell server 822 a& 822 b includes an Ethernet interface to connect it to the local areanetwork (LAN) of the PNE 800. This LAN connection permits the microcellserver 822 a & 822 b to communicate with the PNE central processor andthe radios to perform its control functions. The microcell server 822 a& 822 b coordinate communication between the PNE central processor andthe microcell transceiver banks 820 a & 820 b in use. They also monitornon-responsive radios and dynamically remove them from the active use.The microcell server 822 a & 822 b are also able to relaystatus/diagnostic information and command shut down of radios not in anactive configuration and to report these configuration changes to thePNE central processor. The microcell server 822 a & 822 b also monitorCIC and CMC requests and relay them to the PNE central processor andaccept messages for the CIC and CMC and relay them to the microcelltransceiver banks 820 a & 820 b. The PNE central processor coordinatescall activity within the PNE 800. It processes call requests, callterminations, handoff requests, etc., and downloads control informationto microcell server 822 a & 822 b and communicates with the PSTN 19interface. The PNE central processor performs call setup, call teardown, call routing, and call handoff, and is responsible for performingauthorization and billing. It is externally configurable over theInternet 15 using an Internet 15 interface. The PNE's 800 CentralProcessor essentially creates an electronic map of call activity withinits domain: a Macrocell. This map is the combination of all knownavailable channels in all microcells, all occupied channels, allcontiguous channels, bandwidth availability for CCAP or CCAP+ datatransfers; FIG. 9 & FIG. 10, the number of wireless sets in Active mode,Standby mode or Roaming mode. It also coordinates transfers (hand offs)from one microcell to another suggesting the next available frequencypairs to utilize and logging the previous calls into the ParallelComputing Artificial Intelligence-base Distributive Call Routing System1300 system for analysis or assistance during a catastrophic failure.Tracking of frequency pairs utilized for wireless set to PSE 600 to TSFDwireless ComDoc or TSFD wireless X-DatCom to landline PSTN 19 and timeof day for these activities. The PNE 800 Central Processor coordinatescall activities for the macrocell, and performs authorization, billing,set up, and diagnostic functions. It coordinates calls originating orterminating within the macrocell. Calls may arrive from TSFD wirelesshandset 300 within the macrocell, TSFD wireless handset 300 within adistant macrocell with a dedicated link to this macrocell, or from aPSTN 19. This last case includes calls from a PSTN 19 connection over adedicated PNE 800-PNE 800 link, since not every PNE 800 may have a PSTN19 interface. Signaling from these various sources are evaluated anddisposition of the call is determined. Calls may be routed in (but notlimited to) the following ways:

-   -   1. Within a microcell using the local call mode (no PNE 800        handling of voice data)    -   2. Within the macrocell (routed through PNE 800 switch “a” & PNE        800 switch 800 “b” w/o decompression)    -   3. To a linked PNE 800 (routed through the PNE 800 switch “a” &        PNE 800 switch 800 “b” to the linked PNE 800 w/o decompression)    -   4. To a local PSTN 19 connection (routed through the PNE 800        switch “a” & PNE 800 switch 800 “b” to the PSTN 19 gateway with        decompression)    -   5. To a PSTN 19 connection on a remote PNE 800 (routed between        NEs without decompression and then to PTSN with decompression)

Incoming calls are handled in a similar manner. The signaling is routedseparately from the voice data. The PNE central processor providessource/destination information to the call terminating devices in thesystem (microcell server 822 a & 822 b/radios, PSTN 19 gateway, andremote PNE central processor/PSTN 19 gateway). It does not perform therouting function per PSE 600. For example, if there are two pathsbetween two linked NEs, the PNE central processor depends on the switchto route the call appropriately. The software within the PNE centralprocessor maintains a database of subscribers. Authorized users are ableto add, delete, check status, and modify records associated with TSFDwireless handset 300 using the web page. Specifically, the PNE centralprocessor performs the functions usually associated with theAuthorization Center (AC), Home Location Register (HLR), and VisitorLocation Register (VLR) of traditional cellular systems. The PNE 800supports storage and programming of activation data using a secure webinterface, which provides a way to program the information needed by thePNE 800 to activate TSFD wireless handset 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards 500 or TSFD wireless ComDocs 900. ThePNE central processor monitors outgoing calls, and accumulates a billingrecord of calls that are outside the calling region (i.e., toll calls).The billing record includes the TSFD wireless handset 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 or TSFD wirelessComDocs 900 placing the call via the PNE 800 and the PSTN 19 (i.e.,account number), the number called, time of call, duration of call, andtotal charge for the call. This data is uploadable to a central billingsystem that is external to the PNE 800 over a secure communication link.No billing occurs for Long Distance calls placed via a TSFD wirelesshandset 300-PSE 600-TSFD wireless ComDoc-Home PSTN 19 line. Thisactivity is however, noted and logged by the AI System to determine theload reduction on the PNE's 800 PSTN 19 Interface.

The PNE central processor handles set up information that is in additionto the subscriber records described above. The programmable informationincludes a unique identifier for the PNE 800, numbering information forPSTN 19 links, configuration values for the PNE 800 switch “a” & PNE 800switch 800 “b”, PSTN 19 interface, access to the Internet 15 (forwireless device web browsing) and PNE 800-PNE 800 links. It alsoincludes configuration information for the microcells, includingfrequency block assignments, PSE 600 identifiers, encryption keys, andradio bank configuration (e.g., the number of radios in use for aparticular bank). The PNE central processor supports electronicdiagnostic activities of the PNE 800. Parallel activities are performedand logged by the AI system 1300.

The Internet 15 interface is the physical hardware that interconnectsthe PNE central processor to an Internet 15 service provider (ISP). ThePNE 800 contains a mechanism to move (switch) voice/data betweendifferent radios, the PSTN 19, and external NEs. The switch isdynamically reconfigurable to permit calls to be routed automatically tothe correct destination. The switch is fast enough to permit callswithin a local wireless communication system to operate withoutperceptible delay. The PSTN 19 interface performs the protocolconversion between the typical PSTN 19 interfaces (T1 or E1) and theinternal method used by the PNE 800 switch “a” & PNE 800 switch 800 “b”.The PSTN 19 interface performs out-of-band signaling using SignalingSystem 7 (SS7) signaling protocol, such that the PNE 800 can act as acentral office (CO). The PSTN 19 interface coordinates with the PNEcentral processor to place and receive calls involving the PSTN 19. ThePNE 800 interface provides a fixed voice/data communication link forcall routing to other NEs in the wireless network. The wirelesscommunication system is configurable to support zero, one, or twoexternal NEs. The PNE 800 interface supports three technology types:direct copper connections using DS-1 connections, direct fiberconnections using OC-3 links, and radio links with the DS-1 bandwidth.The PNE 800 includes a control bus for routing data and control betweenthe central processor and the microcell server 822 a & 822 b, a switch,a PNE 800 interface, and a PSTN 19 interface. The control bus may be a10/100Mbps Ethernet LAN (local area network). An uninterruptible powersupply (UPS) 880 a & 880 b is used to power the PNE 800 equipment andbuffer it from the external power grid. In the event of an externalpower grid outage, the UPS battery backup capability is able to operatethe PNE 800 for an extended period of time.

In an alternate embodiment of the present invention, specific InternalSystems: the GPS Reference Source and Distributor; where the PNE 800shall incorporate a Global Positioning System (GPS)-based referencesource 810 a & 810 b for use in stabilizing the local oscillators inTSFD system transceivers. The reference output frequency shall be 10 MHzat the nominal accuracy available from the GPS. The GRP reference source810 a & 810 b shall be used by the PNE 800 transceivers and effectivelytransferred to the PSEs 600 and TSFD wireless handset 300 via theReference Channel downlink. In addition, the GRP reference source 810 a& 810 b shall provide date and time information for the macrocell, whichis broadcast on the RC downlink. The GRP reference source 810 a & 810 bshall include the GPS antenna, and a backup reference source suitable tomaintain frequency tolerance of RF communications channels. The backupsource shall automatically be selected in the event of GPS signal lossor receiver failure. The reference distributor shall provideamplification and fan-out, as necessary, to feed the GPS referencesignal to the Microcell Transceiver Banks. The internal reference shallnot be required to provide time-of-day information. The PNE 800 shalluse directional antennas for communications with the fixed PSE 600sites. The antenna gain shall be at least 15 dBi with a front-to-backratio greater than 25 dB. There shall be one dedicated antenna for eachPSE 600 supported by the PNE 800. Each antenna for a microcell shall beconnected to a Microcell Transceiver Bank 820 a & 820 b within the PNE800. Each Microcell Transceiver Bank 820 a & 820 b shall contain aconfigurable number of transceivers for processing the extended voiceand signaling channels for the associated microcell. The microcell radioprocessor is central to the design of the radio bank. The processorshall be sized to support the functions of the PNE within its domain.The processor shall be software compatible with the TSFD wirelesshandset processor 320 (or other wireless TSFD devices with full softwarereuse. TSFD wireless handset processor 320 (where TSFD wireless handsetmeans any TSFD mobile wireless device) shall have processor peripheralinterfaces for interface to the following items within the PNE:

Vocoder (bi-directional)

Transmitter

Receiver

External Ethernet data connector

The microcell radio processor software shall support the functions ofthe PNE within its domain. The software shall be organized like the TSFDwireless handset 300 software (or other wireless TSFD device), withbootstrap software separate from the operational software. Software fromthe TSFD wireless handset 300 shall be reused for the microcell radioprocessor. Reusable software shall include (but shall not be limited to)the bootstrap, self-test, loader module, modulation, demodulation, andinterface software (for common interfaces). The PNE software shallperform a minimum of the following protocols associated with theEthernet interface:

Ethernet hardware interface

TCP/IP protocol stack

Berkeley sockets

H.248 (if necessary)

The software shall support conversion of voice, data or IntegratedDirect Digital Transfer of live video streaming (packetized) with theTSFD Protocol; FIG. 11, between the internal TSFD format and μ-law. Thesoftware shall support operation as a control channel or voice channel.This configuration shall be possible under command from the PNE CentralProcessor or Microcell Server Processor (MSP 822 a & 822 b). Thesoftware shall also support providing diagnostic information to the PNECentral Processor or MSP 822 a & 822 b on demand. The software shall beable to shutdown the radio to conserve power or for the convenience ofthe PNE Central Processor or MSP 822 a & 822 b. The microcell server 822a & 822 b within the PNE shall connect to radios within the channel bankto perform the control functions associated with a single microcell. Themicrocell server 822 a & 822 b shall communicate with the PNE centralprocessor to route and manage calls that connect outside of themicrocell. The PNE central processor shall be able to direct themicrocell server 822 a & 822 b to promote a call from local mode toassisted mode, change frequency, or perform a handoff betweenmicrocells. The microcell server 822 a & 822 b shall coordinate controlof calls on its microcell, including performing control operations ofradios within its channel bank. The microcell server 822 a & 822 b shallaccumulate the data for the reference channel and feed it to the radiogenerating the RC. It shall also process requests on the CIC and CMC andcoordinate the required actions with the radios in its bank and the PNEcentral processor. A microcell server 822 a & 822 b shall be permittedto handle multiple radio banks.

The microcell server 822 a & 822 b processor (MSP 822 a & 822 b) shallbe an industrial grade unit such as a single board computer. Theprocessor shall include an Ethernet interface to connect it to the localarea network (LAN) of the PNE 800. This LAN connection shall permit theMSP 822 a & 822 b to communicate with the PNE central processor, theradios to perform its control functions and the AI system. The MSP 822 a& 822 b shall be implemented using a ROMable operating system such asWindows XP. The MSP 822 a & 822 b shall permit its operating software tobe downloaded for upgrade using a bootstrap configuration of the system.The MSP 822 a & 822 b shall include no rotating media for reliability.The MSP 822 a & 822 b software shall be a Windows application program.It shall coordinate communications between the PNE central processor andthe microcell radio bank radios. The MSP 822 a & 822 b software shallrelay signaling codes between the radios and the PNE central processor.The software shall also be able to relay status/diagnostic informationand command shut down of radios not in use. It shall be able to monitornon-responsive radios and dynamically remove them from the activeconfiguration. It shall be able to report these configuration changes tothe PNE central processor. The MSP 822 a & 822 b software shall preparethe reference channel data and send it to the appropriate radio. Itshall also monitor CIC and CMC requests and relay them to the PNEcentral processor. The software shall accept messages for the CIC andCMC and relay them to the radio. The PNE central processor shallcoordinate call activity within the PNE 800. It shall process callrequests, call terminations, handoff requests, etc. It shall downloadcontrol information to microcell server 822 a & 822 b and communicatewith the PSTN 19 interface control system. It shall perform call setup,call tear down, call routing, and call handoff. It shall be responsiblefor performing authorization and billing. It shall be externallyconfigurable over the Internet 15 using a secure web interface. Thestatus and controls available over the Internet 15 shall includestopping/starting individual PSEs 600, shutting down the entire system,monitoring system diagnostics, and managing user accounts such asactivating new users. The PNE central processor shall be an industrialPC running Windows NT or XP. PNE Central Processor 830 a & 830 bSoftware; the PNE 800 Central Processor Software (PNECP 830 a & 830 b)shall coordinate call activities for the macrocell, and performauthorization, billing, set up, and diagnostic functions. The PNECP 830a & 830 b (PNE 800 Central Processor Computer) shall coordinate callsoriginating or terminating within the macrocell. Calls may arrive fromTSFD wireless handset 300 within the macrocell, TSFD wireless handset300 within a distant macrocell with a dedicated link to this macrocell,or from the PSTN 19. The last case includes calls from a PSTN 19connection over a dedicated PNE 800-PNE 800 link, since not every PNE800 shall have a PSTN 19 interface. Signaling from these various sourcesare evaluated and disposition of the call is determined. Calls may berouted in the following ways:

-   -   Within a microcell using the local call mode (no PNE 800        handling of voice data)    -   Within the macrocell (routed through PNE 800 switch “a” & PNE        800 switch 800 “b” w/o decompression)    -   To a linked PNE 800 (routed through the PNE 800 switch “a” & PNE        800 switch 800 “b” to the linked PNE 800 w/o decompression)    -   To a local PSTN 19 connection (routed through the PNE 800 switch        “a” & PNE 800 switch 800 “b” to the PSTN 19 gateway with        decompression)    -   To a PSTN 19 connection on a remote PNE 800 (routed between NEs        without decompression and then to PTSN with decompression)

Incoming calls are handled in a similar manner. The signaling shall berouted separately from the voice data. The PNECP 830 a & 830 b shallprovide source/destination information to the call terminating devicesin the system (microcell server 822 a & 822 b/radios, PSTN 19 gateway,and remote PNE central processor/PSTN 19 gateway). The PNECP 830 a & 830b shall not perform the routing function per PSE 600. For example, ifthere are two paths between two linked NEs, the PNECP 830 a & 830 bshall depend on the switch to route the call appropriately.

The PNECP 830 a & 830 b shall provide call progress signalingout-of-band for the following situations: (but not limited to theseexamples)

-   -   Dial tone    -   Busy signal (station is busy)    -   Busy signal (network congestion is occurring)    -   Ring return signal    -   Recording warning signal    -   Bong signal

The PNECP 830 a & 830 b shall maintain a database of subscribers. Thedatabase will be maintainable using a secure website. Authorized userswill be able to add, delete, check status, and modify records associatedwith TSFD wireless handsets 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900 using theSubscriber Database website. The authorization function includeshandling roaming TSFD wireless handsets 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900.The PNECP 830 a & 830 b shall contact the appropriate remote TSFD systemthat is home to the roaming TSFD wireless handset 300, TSFD wirelessX-DatCom 400, TSFD wireless PC-DatCom Card 500 and TSFD wireless ComDoc900 and confirm authorization. Specifically, the PNECP 830 a & 830 bshall perform the functions usually associated with the AuthorizationCenter (AC), Home Location Register (HLR), and Visitor Location Register(VLR) of traditional cellular systems.

The Operational State of the Subscriber Database can be controlled inthe following manner by the PNE 800:

-   -   1. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP 830 a & 830        b's internal Memory.    -   2. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE 800 housing or by such portable data storage medium as will        facilitate uploading new data control instructions when inserted        in the PNECP 830 a & 830 b's data drives.    -   3. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the TSFD Network.    -   4. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the PSTN 19, the Internet        15, direct copper connections using DS-1 connections, direct        fiber connections using OC-3 links, radio links with the DS-1        hardware, an Earth-Satellite ground station for direct two-way        communications with telecom satellites, the sending and        receiving of short haul, ultra-wide-band optical communications        via modulated Laser links.    -   5. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by transmissions        from the Parallel Computing Artificial Intelligence-base        Distributive Call Routing System 1300-based Distributive Routing        Computer located within the Environmental Housing of the PNE        800.    -   6. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by transmissions        from an Parallel Computing Artificial Intelligence-base        Distributive Call Routing System 1300-based Distributive Routing        Computer located within the TSFD PNE's 800 operational service        area of captive PSEs 600 during a catastrophic failure within        the TSFD Network.        The Dynamic State of the Subscriber Database can be controlled        in the following manner by the PNE 800:    -   1. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Dynamic State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP 830 a & 830        b's internal Memory.    -   2. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Dynamic State Control over the Subscriber Database,        located on a website on the Internet 15, containing all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE 800 housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP 830 a & 830 b's data drives.    -   3. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over the Subscriber Database, located on a website        on the Internet 15, containing all TSFD wireless handset 300,        TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500        and TSFD wireless ComDocs 900 for activation, deactivation and        billing privileges by programming instructions received by        transmissions from remotely located TSFD Network authorized        personnel via the TSFD Network.    -   4. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over the Subscriber Database, located on a website        on the Internet 15, containing all TSFD wireless handset 300,        TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500        and TSFD wireless ComDocs 900 for activation, deactivation and        billing privileges by programming instructions received by        transmissions from remotely located TSFD Network authorized        personnel via the PSTN 19, the Internet 15, direct copper        connections using DS-1 connections, direct fiber connections        using OC-3 links, radio links with the DS-1 hardware, an        Earth-Satellite ground station for direct two-way communications        with telecom satellites, the sending and receiving of short        haul, ultra-wide-band optical communications via modulated Laser        links.    -   5. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over the Subscriber Database, located on a website        on the Internet 15, containing all TSFD wireless handset 300,        TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500        and TSFD wireless ComDocs 900 for activation, deactivation and        billing privileges from programming instructions received by        transmissions from the Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   6. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over the Subscriber Database, located on a website        on the Internet 15, containing all TSFD wireless handset 300,        TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500        and TSFD wireless ComDocs 900 for activation, deactivation and        billing privileges from programming instructions received by        transmissions from an Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the TSFD PNE 800's        dynamic service area of captive PSEs 600 during a catastrophic        failure within the TSFD Network.

PNE 800 Billing: the PNECP 830 a & 830 b shall monitor outgoing calls.Calls that are outside the TSFD calling region (i.e., toll calls) shallcause the PNECP 830 a & 830 b to accumulate a billing record. Thebilling record shall include the TSFD wireless handset 300, TSFDwireless ComDoc and/or TSFD wireless X-DatCom placing the call (i.e.,account number), the number called, time of call, duration of call, suchtariffs as apply and total charge for the call. This data shall beuploadable to a central TSFD billing system that is external to the PNE800 over a secure Internet 15 link. The format of this billing data andlocation of storage is defined by whatever commercially availablesoftware is available and most suited to the task. PNE 800 Setup; thePNECP 830 a & 830 b shall include set up information on the securewebsite that is in addition to the subscriber records described above.The programmable information shall include a unique identifier for thePNE 800, numbering information for PSTN 19 links, configuration valuesfor the PNE 800 switch “a” & PNE 800 switch 800 “b”, PSTN 19 interface,and PNE 800-PNE 800 links. It shall also include configurationinformation for the microcells including frequency block assignments,PSE 600 identifiers, encryption keys, and radio bank configuration (e.g,the number of radios (and their position in the system) in use for aparticular bank. Call-load handling algorithms, methods for securing androuting flexible bandwidth (CCAP or CCAP+) requests by subscribers fordata transmissions within the PNE 800 Domain, dynamic (Ongoing andPending Calls) storage of local voice and extended voice paths withinthe entire PNE 800 Macrocell, amount of PSTN 19 Interface usage (CallLoad) savings generated by TSFD wireless handset 300, TSFD wirelessX-DatCom 400, TSFD wireless PC-DatCom Card 500 and TSFD wireless ComDoc900 Direct Access to PSTN 19 Landlines, shall also be stored. It mustalso be noted that the Parallel Computing Artificial Intelligence-baseDistributive Call Routing System 1300-based Distributive Routing System1300 shall have access to this setup information from the same securewebsite should the AI system detect a catastrophic failure of the PNE800 or other such systems which could impair the PNE 800 from performingits assigned duties within the TSFD Network. PNE 800 Diagnostics; thePNECP 830 a & 830 b shall support diagnostic activities of the PNE 800.The PNECP 830 a & 830 b shall provide maintenance personnel a diagnosticinterface over a secure website or on site from a keyboard, monitor andprinter. The PNECP 830 a & 830 b shall provide the authorized user a wayto command diagnostic reports from all subsystems (such as the microcellradio bank) and view the report data. The PNECP 830 a & 830 b shall alsoperform scheduled, automated, diagnostic tests of all subsystems andstore these reports on the secure website. The PNECP 830 a & 830 b alsodelivers this accumulated diagnostic data to the AI Interface. PNE 800Internet 15 Interface; the Internet 15 interface is the physicalhardware that interconnects the PNE central processor to the Internet 15service provider (ISP). This Interface shall provide security featuresfrom the latest commercially available software and hardware. TheInternet 15 Interface shall access wideband cable ISP services.

In an alternate embodiment of the present invention, the AI Interface isthe physical hardware that interconnects the PNE central processor to adiscrete, Parallel Computing Artificial Intelligence-base DistributiveCall Routing System 1300 software programmed PC style computer operatingin the Microsoft Windows NT or XP format. The AI Interface allows anexchange of information between the PNE 800 Central Processor and the AIcomputer for the monitoring of internal electronic systems, efficiencyof PNE 800 routing, call load evaluations, call distribution analysisbetween PSEs 600, number of TSFD wireless handset 300, TSFD wirelessX-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD wirelessComDocs 900 present and active on the TSFD network, etc. The AIInterface allows communication with the PNE 800 Central Processor tosuggest re-routing of excessive call loading, suggest redistribution ofdata traveling on the TSFD Network between TSFD wireless ComDoc's orTSFD wireless handset 300 and Computers utilizing the CCAP or CCAP+Sub-protocol of TSFD or changing the operational state of ANY of thesystems or subsystems on the TSFD Network. PNE 800 Switch; the PNE 800shall contain mechanisms to move (switches) voice data between differentradios, the PSTN 19, and external NEs. These switches shall bedynamically reconfigurable to permit calls to be routed automatically tothe correct destination. They shall be fast enough to permit callswithin a local TSFD network to operate without perceptible delay. Theseswitches shall perform with minimal jitter so as to preservenear-toll-quality calls. Switches shall also be present to deactivatethe Circuit “A” PNE 800 Primary Circuitry and activate Circuit “B” PNE800 Secondary Circuitry during a catastrophic failure of the PrimarySystem. This activation shall be dynamically reconfigurable by the AISystem to affect the most reliable transfer of duties between the “A”and “B” circuits. PNE 800 PSTN 19 Interface; the PSTN 19 interface shallperform the protocol conversion between the typical PSTN 19 interfaces(T1 or E1) and the internal method used by the PNE 800 switch “a” & PNE800 switch 800 “b”. The PSTN 19 interface shall perform out-of-bandsignaling using Signaling System 7 (SS7) signaling protocol, such thatthe PNE 800 can act as a central office (CO). The PSTN 19 interfacecontrol computer shall coordinate with the PNE central processor toplace and receive calls involving the PSTN 19. The number of external T1or E1 lines connecting the PNE 800 with the PSTN 19 is entirely afunction of the number of PSEs 600 deployed within the domain of the PNE800; the macrocell. The number of wireless subscribers within the systemwill likely generate a PSTN 19 user connection level of approximately12% based upon case histories of landline service. This will dictate thenumber of interface connections between PSE 600's and the PSTN 19through the PNE 800. TSFD wireless ComDocs 900 however, will lightenthis load as subscribers discover the ease of connecting to a landlinethat is unused. This alternative to external network connections lowersthe business operating cost of the PNE 800 system operator and furthersimplifies the infrastructure. Further simplicity is ensured as thecalling load on the PNE 800 can be reduced giving the PNE 800 a lowerfailure rate due to electronic fatigue.

The PNE 800 Interface shall provide a fixed voice/data communicationslink for call routing to other NEs in the TSFD network. The PNE 800design shall be configurable to support zero, one, or two external NEs.The PNE 800 Interface design supports five technology types as follows.First, direct copper connections using DS-1 connections shall besupported. Second, direct fiber connections using OC-3 links aresupported. Third, radio links with the DS-1 hardware. Fourth, anEarth-Satellite ground station for direct two-way communications withtelecom satellites. Fifth, a method for the sending and receiving ofshort haul, ultra-wide-band optical communications via modulated Laserlinks. The PNE 800 design architecture permits redundant links betweenNEs for network reliability.

The PNE 800 shall include a Control Bus for routing data and controlbetween the Central Processor and the Microcell Servers, Switch, PNE 800Interface, and PSTN 19 interface. The Control Bus may be a 10/100 MbitEthernet LAN (local area network).

The Uninterruptible Power Supply (UPS) is used to power the PNE 800equipment and buffer it from the external power grid. The PNE 800equipment power draw from the UPS will not exceed 2,500 Watts. In theevent of an external power grid outage, the UPS battery backupcapability shall be able to operate the PNE 800 for at least one hour.The batteries shall be rated to last at least 5 years in the fieldwithout replacement. The UPS shall include a master power switch. Theenvironmental package for the electronics at the PNE 800 shall providedry, clean, temperature-controlled air for the PNE 800 electronics. Thepackage shall also provide lightning protection for enclosed equipment.Security and controlled access are included in the computer controlledentry interlocks. Biometrics may be utilized to admit only thoseindividuals specifically certified within the security system'sdatabase. Unauthorized attempts to access the environmental enclosure ofa PNE 800 will alert the AI system and authorized personnel.

In a further illumination of the present invention, the OperationalState of all TSFD Subsystems can be controlled in the following mannerby the PNE 800:

-   -   1. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Static State Control over all TSFD wireless handset        300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards        500 and TSFD wireless ComDocs 900 for activation, deactivation        and billing privileges by predetermined and defined software        parameters stored in the PNECP 830 a & 830 b's internal Memory.    -   2. The PNE 800 exercises Static State Control over all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE 800 housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP 830 a & 830 b's data drives.    -   3. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        TSFD Network.    -   4. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        PSTN 19, the Internet 15, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   5. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from the Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   6. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from an Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the TSFD PNE's 800        operational service area of captive PSEs 600 during a        catastrophic failure within the TSFD Network.    -   7. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by programming instructions received from predetermined and        defined software parameters stored in the PNECP's 830 a & 830 b        internal Memory.    -   8. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by external programming instructions received from a keypad,        touch-active video screen within the PNE 800 housing or by such        portable data storage medium as will facilitate uploading new        data instructions when inserted in the PNECP 830 a & 830 b's        data drives.    -   9. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from        remotely located TSFD Network authorized personnel via the TSFD        Network.    -   10. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from        remotely located TSFD Network authorized personnel via the PSTN        19, the Internet 15, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   11. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by hard-wired data        transmissions from the Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   12. The PNE Central Processor 830 a & 830 b exercises Static        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from an        Parallel Computing Artificial Intelligence-base Distributive        Call Routing System 1300-based Distributive Routing Computer        located within the TSFD PNE 800's operational service area of        captive PSEs 600 during a catastrophic failure within the TSFD        Network.

The Dynamic State of all TSFD Subsystems can be controlled in thefollowing manner by the PNE 800:

-   -   1. The PNE Central Processor 830 a & 830 b (PNECP 830 a & 830 b)        exercises Dynamic State Control over all TSFD wireless handset        300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards        500 and TSFD wireless ComDocs 900 for activation, deactivation        and billing privileges by predetermined and defined software        parameters stored in the PNECP 830 a & 830 b's internal Memory.    -   2. The PNE 800 exercises Dynamic State Control over all TSFD        wireless handset 300, TSFD wireless X-DatComs 400, TSFD wireless        PC-DatCom Cards 500 and TSFD wireless ComDocs 900 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE 800 housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP 830 a & 830 b's data drives.    -   3. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        TSFD Network.    -   4. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges by programming instructions received by transmissions        from remotely located TSFD Network authorized personnel via the        PSTN 19, the Internet 15, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   5. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from the Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   6. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all TSFD wireless handset 300, TSFD wireless        X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFD        wireless ComDocs 900 for activation, deactivation and billing        privileges from programming instructions received by        transmissions from an Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the TSFD PNE 800's        dynamic service area of captive PSEs 600 during a catastrophic        failure within the TSFD Network.    -   7. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by programming instructions received from predetermined and        defined software parameters stored in the PNECP 830 a & 830 b's        internal Memory.    -   8. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by external programming instructions received from a keypad,        touch-active video screen within the PNE 800 housing or by such        portable data storage medium as will facilitate uploading new        data instructions when inserted in the PNECP 830 a & 830 b's        data drives.    -   9. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from        remotely located TSFD Network authorized personnel via the TSFD        Network.    -   10. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from        remotely located TSFD Network authorized personnel via the PSTN        19, the Internet 15, direct copper connections using DS-1        connections, direct fiber connections using OC-3 links, radio        links with the DS-1 hardware, an Earth-Satellite ground station        for direct two-way communications with telecom satellites, the        sending and receiving of short haul, ultra-wide-band optical        communications via modulated Laser links.    -   11. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by hard-wired data        transmissions from the Parallel Computing Artificial        Intelligence-base Distributive Call Routing System 1300-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   12. The PNE Central Processor 830 a & 830 b exercises Dynamic        State Control over all PSEs 600 for activation and deactivation        by programming instructions received by transmissions from an        Parallel Computing Artificial Intelligence-base Distributive        Call Routing System 1300-based Distributive Routing Computer        located within the TSFD PNE 800's dynamic service area of        captive PSEs 600 during a catastrophic failure within the TSFD        Network.        PNE 800 RF Transmission Methodology: the present Time Shared        Full Duplex (TSFD) PNE 800 and corresponding wireless        communication system utilizes the Broadband PCS radio frequency        spectrum, licensed in the United States by the FCC (Federal        Communications Commission).

It should be noted however, TSFD is not limited technologically and mayalso be programmed for operations at other available frequencies aroundthe world. TSFD may also be operated at substantially more restrictedbandwidths or fundamentally higher frequencies than conventional PCS.The frequency range of 50 MHz to 5 GHz have been proven suitable forTSFD Protocol operations; however, with lower frequencies creating asubstantial reduction in users of wireless devices when on the system.It has also been shown that a substantial transmission range increase isobserved in the lower frequencies with a significant reduction in signaldegradation. Frequencies above the “Hydrogen absorption” frequency(around 2.4 GHz) exhibit easy signal degradation with significant lossesattributed to fog, rain, smog, pine needles, obstructions, etc., yetyielding an extraordinary subscriber load. Distance is alsosignificantly decreased and line-of-sight is essential. Shorter distancemeans greater numbers of PSEs 600 increasing deployment costs. Thefrequency range that the Time Shared Full Duplex (TSFD) PNE 800 andcorresponding wireless communication system covers in this U.S.A.disclosure, FIG. 4 and FIG. 5, is between 1850 megahertz and 1990megahertz, and includes PCS low band and PCS high band. Licenses must beacquired for one or more PCS blocks, designated by the United StatesFederal Communications Commission as blocks “A through F”. The PCS lowband 42 is reserved for PSE 600 Receive frequencies, and the high band44 for PSE 600 Transmit frequencies. Half of each band is reserved forsignals between the PSEs 600 and the TSFD wireless handset 300, orbetween PSE 600's, TSFD wireless ComDocs 900 and TSFD wireless X-DatComs400, with the other half for signals between the PSEs 600 and the PNE800. A TSFD wireless ComDoc and the TSFD wireless X-DatCom communicatewith a PSE 600 in the same manner that a TSFD wireless handset 300communicates with a PSE 600. With duplex filtering and 80-MHz separationbetween the low band and high band, the PSE 600 can simultaneouslyreceive and transmit signals without compromising receiver sensitivity.This frequency plan allows calls to take place asynchronously, whichsimplifies the design. Although many possible timing architectures maybe used in the present wireless communication system, an asynchronoussystem architecture is selected to provide the best fit to the keyrequirements of cost, range and user density. This architecture ortransmission “protocol” further simplifies the operations of the PNE 800as this vital system component coordinates, but does not ultimatelycontrol, TSFD Network operations. Asynchronous operation of the presentwireless communication system allows greater flexibility in systemgeographic layout, simpler digital protocol, and channel separationstructure. Conventional digital cellular and PCS systems are designedsuch that synchronous operation with a tower structure is a necessity.CDMA cellular/PCS systems require synchronous operation to insuredemodulation and precise coordination of power control and TDMAcellular/PCS systems require synchronous operation to prevent time slotinterference. Synchronous operation allows the system design to makevery efficient use of the assigned spectrum (high user density) for agiven size geographic area for a trade-off in system complexity, cost,and flexibility. Synchronous operations require substantially moreelectronic hardware and far more complex software than the presentlydisclosed asynchronous wireless communications system. The presentwireless communication system has lower density requirements (ruralenvironment), so the advantages of asynchronous operation became verybeneficial to the required cost effectiveness of the present systemdesign. The present Time Shared Full Duplex (TSFD) PNE 800 andcorresponding wireless communication system allows the PCS bands to befurther divided into sub-bands dedicated for each of the 9 microcelltypes. Each microcell uses the sub-bands assigned for its particulartype (alpha-numeric designator A1, A2, A3, B1, B2, B3, C1, C2, or C3) inorder to preclude interference with adjacent microcells (since adjacentmicrocells are never of the same type). As illustrated in FIG. 3 andFIG. 4, these microcell sub-bands are 825 kHz wide for PCS blocks ABC,and 275 kHz wide for blocks DEF. The definition of 9 microcell typesprovides two additional non-adjacent types beyond the minimum 7 that arerequired for a hexagonal cell layout with frequency division multipleaccess (FDMA) shown below in “The Macrocell Frequency Division MultipleAccess” diagram.

In an alternate embodiment, turn now to the territorial illustration,FIG. 3, of the Operational Domain of a PNE 800 servicing itscorresponding wireless communication system. For a microcell in thisdisclosed cell pattern illustrated in FIG. 3, the additional twonon-adjacent types are the other two alpha designators with the samenumeric designator. For example, the sub-bands for microcell types A2and C2 are not used in the microcells adjacent to microcell B2.Sub-bands A1ML, A2ML, A3ML, B1ML, B2ML, B3ML, C1ML, C2ML and C3ML areassigned to communication from a TSFD wireless handset 300, TSFDwireless X-DatCom 400, TSFD wireless PC-DatCom Card 500 and TSFDwireless ComDoc 900 to a PSE 600. Sub-bands A1MH, A2MH, A3MH, B1MH,B2MH, B3MH, C1MH, C2MH and C3MH are assigned to communication from a PSEto a TSFD wireless handset 300, TSFD wireless X-DatCom 400, TSFDwireless PC-DatCom Card 500 and TSFD wireless ComDoc 900. Sub-bandsA1XL, A2XL, A3XL, B1XL, B2XL, B3XL, C1XL, C2XL and C3XL are assigned tocommunication from a PNE 800 to a Signal Extender. Sub-bands A1XH, A2XH,A3XH, B1XH, B2XH, B3XH, C1XH, C2XH and C3XH are assigned tocommunication from a PSE to a PNE 800.

In a further embodiment of this invention, FIG. 4 illustrates theSub-band communication layout in a TSFD Protocol system coordinated by aTSFD PNE 800.

In an alternate embodiment of the invention, FIG. 22 and FIG. 23 furtherillustrate: PNE 800 Rf Transmission Methodology; within the OperationalDomain of a TSFD PNE 800 servicing its corresponding wirelesscommunication system, the PNE 800 utilizes a de facto centralized calllogging system. Although, the PNE 800 does not switch calls withinMicrocells; i.e. between (portable TSFD Devices) separate TSFD wirelesshandset 300 or TSFD wireless handset 300, TSFD wireless X-DatComs 400,TSFD wireless PC-DatCom Cards 500 or TSFD wireless ComDocs 900, the PNE800 does keep track of all used and unused “channels” within eachMicrocell. A PNE 800 does complete routing from discrete PSE's 600 toother wireless devices or to external networks. Registration of TSFDwireless handset 300 (digital locking of a wireless TSFD wirelesshandset 300 into a PCS tower's control—Time code or Code controlsynchronous system) within a network, typical of PCS style wirelessdevices, is not required within the PNE's 800 territorial domain. Thisis unnecessary within TSFD protocol rules. However, when a portable TSFDdevice is “On” and ready for communication (sending or receiving) itdoes notify the PNE 800 of its presence through the nearest PSE 600'sCall Initiation Channel, CIC. This “presence” and its MicrocellNumerical Designation are logged as a reference by the PNE 800. Furtherannouncements are unnecessary as the device is in a “Standby” mode readyfor receiving a call. The wireless device receives ALL requests for acall “Connect” and merely references its own number against the numberbroadcast over the CIC for an acknowledged completion. No signals orcarriers are generated in any channel pairs (Upper and Lower FrequencyBlocks, as illustrated in FIG. 4) unless a call is initiated. This low“pressure” on the electromagnetic environment reduces noise andcompletely eliminates crosstalk in the TSFD network. With this conceptestablished, it is prudent to define the role of the PNE 800 infrequency stability throughout the TSFD Network; the TSFD PNE 800 hasbeen shown to provide a GPS-based and Network rebroadcast timing signal.The primary necessity of such a signal is the fact that no broadcastcarriers exist in any systems in the TSFD network unless transmissionsare in play. Therefore, it becomes necessary to establish certainty thata “Channel Pair” (say, Channel Pair Number 98) in one wireless deviceare the exact frequency Pair in all other wireless devices within theTSFD Network. Frequency drift in a narrowband transmission system is notacceptable. Locking in the GPS signal allows for frequency feedbackloops to constantly retune digitally controlled frequency circuits tocorrect any potential frequency drift. Temperature variations due tocrystal frequency drift in an oscillator are thus avoided and greatlysimplified. However, it is extremely important to provide a temperaturecontrolled backup crystal frequency oscillator for this referencefrequency in every PNE 800 should the GPS system fail from some eventsuch as a solar flare or a meteor shower.

In an alternate embodiment of the present invention, the terms BackupSystems—Redundancy are examined; wherein a PNE 800 cannot afford to be“offline”. There will however, be inevitable events which render thesystem inoperative. It is therefore, imperative to specify electronicredundancy. Redundancy in its purest form however; i.e., a completeduplicate-backup system, is rejected in favor of a live, a deployment ofparallel active circuitry capable of assuming total operations shouldany one of the separate circuits become inoperative.

As illustrated in FIG. 22 and FIG. 23 of this embodiment of theinvention, the entire circuitry of the PNE 800 is operated in parallelshould there be any detected system failure. Internally, the volatilememory is not specifically backed up but operates in a Circuit A's, FIG.22 and Circuit B's, FIG. 23, parallel architecture. The hard drive inCircuitry “A” runs fulltime as a live drive; i.e. a drive which is fullyoperational with an exact working copy of all drive information. Such aparallel hard drive system is also found in the Secondary Circuitry “B”backup. This second drive pair also continuously acts as live drives tothe Circuitry “A” drive pair. This assures a continuity of operationsand information retention should Circuitry “A” fail completely.Administration of a switchover during failure is managed by the AIsystem. All switchovers of mechanical or electronic nature areaccomplished by digital control over switching and routing devices andcircuits for that purpose by the AI system or manually by keyboardinstructions from human technicians. Further, all electronic subsystemsin all TSFD PNE's 800 Circuitry “A” and in Circuitry “B”, are wired toprovide test points that are continuously monitored for safe operationsby the AI Oversight system. A performance log is generated and storedfor human and AI analysis. Following any suspicious (out of systemspecifications) measurements, the AI system alerts human servicetechnical personnel via fax, wireless device, landline telephone, pageror other such method that has been established. The AI systemincorporates vocalization and speech to precisely identify the problemaurally over the telephone or wireless device.

GPS-Based Wireless Device Location System within the Domain of a TSFDProtocol PNE 800; the triangulation analysis of Signal Extender-receiveddistress calls from wireless devices located within the Domain of a TSFDPNE's 800 Microcells is the job of AI's analysis system. Individualwireless devices receive, continuously, the time, date and PSEIdentification code via the nearest PSE 600. They also receive the GPStiming code for circuit stabilization. When a distress call to 911 isgenerated by the device user, the device bursts a 2 watt coded signalout to the surrounding area. The signal is burst for a period ofmilliseconds on the Distress Channel reserved for such communication andrepeated until it is acknowledged automatically by the nearest PSE'sDistress Call Sensor.

The PSE 600 time and date stamps the received signal and compares it tothe encoded time and date stamp broadcast from the wireless device. TheDistress Sensor and AI system in the PSE 600 calculate the distancemeasurement code generated by the subtraction time of the PSE 600 timeand the Device time or transmission. This code is sent to the PNE 800.It is assumed that a 2 watt signal will be received by at least twoother PSEs 600. Since the PSE 600's do not have a way to determinedevice direction from their towers, a distance circle is generatedaround the PSE 600's receiving the distress signal within the AIsoftware. Since the individual PSE 600's are generally differentdistances from the distress caller's transmission point, the PSE 600'sdistance circles should intersect on a hypothetical AI map. Thislocation is determined by the PNE 800 AI system and will then determinethe exact transmission point of the distress call. Once the position isprecisely resolved, the PNE's AI system 1300 will initiate a call tolocal civil authorities with a patch-through call completion from thedistressed caller. Completion time should be well within 45 seconds forthe caller's location to appear on the EMS Call Center operator'scomputer screen. The format of this exercise in an interface mode withcivil authorities will be that format which is required in whateverlocation the TSFD PNE's 800 Domain occupies. Scientific estimates ofTSFD PNE 800 AI Analyzed location for wireless device distress callswithin a Macrocell are projected to be within 1 to 10 meters ofcertainty; based upon timing frequencies utilized.

In a further embodiment of the present invention, the methodologies ofRF transmission oversight and routing must be detailed and examined andthe specific responsibilities of the PNE 800 disclosed. FIG. 24 and FIG.25 depict the physical relationships between TSFD wireless handset 300,PSEs 600, a PNE 800, microcells and a macrocell.

A macrocell is able to utilize the full amount of PCS spectrum that islicensed. This is achieved by including at least one microcell of eachof the 9 types (A1-3, B1-3, and C1-3) in a macrocell, previouslyreferenced. In addition, spectrum may be reused within a macrocell amongnon-adjacent microcells and through the use of directional antennas forthe PSE 600-to-PNE 800 communication links, which are between fixedsites. The radio frequency (RF) waveform is produced using GMSK(Gaussian Minimum Shift Keying) modulation with a data rate of 16 kbps.Baseband filtering limits the 3-dB channel bandwidth to 12.5 kHz. Theresultant waveform is a “constant envelope” type, meaning that there isno intended amplitude modulation. The wireless communication system RFcoverage and range depend upon the RF parameters of the system(frequency, bandwidth, transmit power, receive sensitivity, antennagain, etc.), the radio horizon, and the amount of signal occlusion inthe line-of-sight between the PSE 600 and TSFD wireless handset 300. TheRF parameters are specified so that the radio horizon is normally thelimiting factor. The radio horizon is a function of the antenna heightsand curvature of the earth. As an example, a PSE 600 antenna on top of a100-foot tower can “see” TSFD wireless handset 300 located out to about14 miles actual ground distance from the base of the tower. Terrain andman-made structures present the potential for signal occlusions, i.e.,non-line-of-sight conditions, which reduce effective coverage and range.Urban propagation models for RF signals show a significant decrease inrange compared to clear line-of-sight conditions. For example, the RFconditions that yield 253 miles of range when operated with a clearline-of-sight yield only 4 miles with the urban model. The deployment ofthe wireless communication system in rural areas alleviates thepotential for urban occlusions, but terrain is still a factor.Microcell/macrocell layout and PSE 600/PNE 800 antenna site selectionwill be required for each installation based on careful planning,consideration, and test of the propagation conditions and physicalconstraints of the geographical area. The use of the 1.9-GHz PCSspectrum affects the range, amount of multi-path generated, and signalpenetration capability compared to other frequency bands such as VHF andUHF, and therefore must be considered in site layout and planning.

In an additional embodiment of the invention, the phrase: TSFD PNE 800:Channelization Protocol is examined and illustrated. It is extremelyimportant to understand the role of the PNE 800 in the operations of theentire TSFD Device compliment. Though autonomous in operation anddesign, all TSFD wireless systems and subsystems depend on the“guidance” of the PNE 800. When a call is made from one TSFD wirelesshandset 300 (“handset” can be understood to mean, in this discussion,any TSFD wireless devices) to another within a single microcell (withinthe coverage of one tower), the PNE 800 provides critical spectrum dataallowing the TSFD wireless devices to access channels which areunoccupied. This data is also critical should one or both of thewireless sets physically leave the transmission area of the originatingtower. Help with choosing a path for the signal to be maintained, (ahandoff) is the job of the PNE 800. Knowing the previously occupiedchannels are now vacant is imperative. It therefore becomes extremelynecessary for the system as a whole to “log” this change in locationshould another wireless set try to access the area where the first twodevices originated. Without the PNE 800 keeping track of what channelsare occupied throughout the entire system, the wireless sets would haveto be extremely complicated and cumbersome. Channel monitoring by eachTSFD wireless device (TSFD wireless handset 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards 500 or TSFD wireless ComDocs 900) ofALL channels would be required and knowledge of the availability ofchannel pairs in other microcells would be unknown. A detailed knowledgeof the methods and techniques of signal packaging, transmission andreceiving between all TSFD wireless systems and subsystems is criticalto understanding the “oversight role” of a TSFD PNE 800. How thespectrum is allocated and managed within the “domain” of a PNE 800 is ofextreme importance. The PNE 800 makes suggestions on the routing oractually connects calls between wireless sets located in differentmicrocells or from wireless sets within the TSFD system to telephonesoutside the PNE's 800 Domain. None of these actions can take placewithout methodologies (switching and allocation algorithms) inherent inthe central processor of the PNE's 800 core electronics.

In an additional embodiment of the invention, the phrase: PNE 800 RadioFrequency Channelization Plan is reviewed and illustrated. Thechannelization protocol includes elements of control (signaling) anddata (voice/data). The available RF spectrum is broken down intovoice/data and signaling channels. To further illustrate an additionalembodiment of the invention, FIG. 26 describes the number of channelsper microcell per PCS block. All of these channels are “administered” bythe PNE 800. Local Path channels, of which there are thousands(frequency reuse within the domain of the PNE 800), are tracked andsuggestions for routing are made to the TSFD wireless devices attemptingto complete calls without their signal traveling through the PNE 800.Knowing which channel pair is available for transmission without havingto search the spectrum keeps the complexity of the TSFD wireless devicesto a minimum. It also facilitates handing off the call when the wirelessdevice begins moving outside the Local Path (Local Path: calls within asingle PSE 600 where another wireless device is also residing) callingparameter; i.e. to another PSE 600. The total number of extended pluslocal channels may not be available for simultaneous use. A minimumtotal of 96 channels are required. Channels are comprised of atransmit/receive pair of frequencies separated by 80 MHz. The TSFDwireless handset 300 uplink (TSFD wireless handset 300 to PNE 800) usestwo channel halves, one for TSFD wireless handset 300 to PSE 600, andone for PSE 600 to PNE 800. Similarly, the TSFD wireless handset 300downlink (PNE 800 to TSFD wireless handset 300) uses the other halves ofthe same two channels, one for PNE 800 to PSE 600, and one for PSE 600to TSFD wireless handset 300. The PSE 600 provides the necessaryfrequency translation for both the uplink and downlink; withoutdemodulation or timing, as in traditional PCS systems. TSFD wirelesshandset 300 and PNE 800 channel pairs are different, but 80 MHzseparates each pair. The fixed 80-MHz offset is built into the TSFDwireless handset 300 and PNE 800 transceiver designs to allow formicrosecond switching between receive and transmit functions. Local pathcalls present an exception to the channel concept described in thepreceding discussion because these calls do not have an uplink/downlinkwith the PNE 800. As a result, they use only one channel pair, which isshared between the two TSFD wireless handsets 300. The PSE 600 is stillrequired to provide the frequency translation. However, as mentionedbefore, the PNE 800 is still required to advise exactly which channelpair is available within the microcell, though no voice/data signalsduring the call actually enter the PNE 800 for switching. Voice or dataframes and packets are used to exchange information between a TSFDwireless handset 300, a TSFD wireless PC-DatCom Card 500, a TSFDwireless ComDoc, a TSFD wireless X-DatCom or a PNE 800. A number ofvoice data channels (VDCs) are used in each microcell to carryvoice/data call traffic in the wireless communication system. Each VDCis dedicated to a single call (i.e., voice/data channels are notmultiplexed) to simplify the design. Two VDC types are defined, extendedpath and local path. Four fixed physical frequencies from the microcellsub-band spectrum are allocated for each extended VDC (i.e., uplink fromTSFD wireless handset 300 to PSE 600, uplink from PSE 600 to PNE 800,downlink from PNE 800 to PSE 600, and downlink from PSE 600 to TSFDwireless handset 300).

Further illustrative of the present invention: in contrast, thefrequencies for the local VDCs are allocated from the sub-band spectrumof one of the two non-adjacent microcell types, which are identified bydifferent alpha, but same numeric designator. For example, in microcelltype B2, the local VDCs use the frequencies from microcell type A2 orC2. Since these cells are non-adjacent, interference is precluded. It isnoted that for the local VDC, only two fixed physical frequencies arerequired (i.e., uplink from TSFD wireless handset 300 to PSE 600,downlink from PSE 600 to TSFD wireless handset 300) since the PNE 800 isnot utilized. Local VDCs are contained within the microcell, whileextended VDCs are connected through the PNE 800 to other microcells,macrocells, and/or the PSTN 19. Calls between TSFD wireless handset 300located in the same microcell use local VDCs to increase system capacityby reducing the number of calls switched through the PNE 800. The use ofseparate sub-band blocks for extended and local path/data channelsallows the PSE 600 to relay the extended VDCs to the PNE 800, and thelocal VDCs back within the microcell for receipt by other TSFD wirelesshandset 300. The number of VDCs in a microcell depends on the amount ofspectrum that is available: 38 VDCs (19 local, 19 extended) in a 5-MHzblock (D, E, or F) or 96 VDCs (63 max local, 63 max extended) in a15-MHz block (A, B, or C). One VDC is required for each call in amicrocell. Extended VDCs support one TSFD wireless handset 300 or TSFDwireless ComDoc. Local VDCs support two TSFD wireless handsets 300, or aTSFD wireless handset 300 and a TSFD wireless ComDoc, but still only onecall. The advantage of the local VDC is that the TSFD wireless handset300 share the channel (which saves a VDC), and the complementarychannels for the uplink/downlink are not required (which saves two moreVDCs). The result is one channel pair required versus four channel pairsfor an extended path call. Whenever one of the TSFD wireless handset 300on a local VDC call leaves the microcell, the call must be handed off toseparate extended VDCs for each TSFD wireless handset 300. The VDCprotocol is half-duplex on the physical channel, but is effectively fullduplex from the user's perspective. This is achieved by buffering andencoding the digitized voice data, and transmitting it in packets at ahigher data rate than is required for realtime decoding. As a result,the TSFD wireless handset 300 or any TSFD wireless device, is able totoggle back and forth between its transmit and receive functions at aneven rate (50% transmit, 50% receive). The alternating transmit-receive“ping-pong” approach of TSFD is an advantage over traditional methods.(also saves batteries in a mobile wireless set and reduces head exposureto microwave emissions due to 50% active transmissions) Full-duplextransmit and receive functionality is not required of the TSFD wirelesshandset 300 or other wireless TSFD devices. Consequently the TSFDarchitecture specifies a transmit/receive (TR) switch instead of aduplexer, to significantly reduce cost, size, and weight. A 40 ms voiceframe (20 ms transmit window, 20 ms receive window) will also beutilized, based on the vocoder (voice encoder/decoder) packet size. Theframe length sets the minimum buffering delay since the voice signalmust be fully acquired in realtime and packetized before transmission.Delays due to frame lengths much above 40 ms may become perceptible tothe user. On the other hand, short frame lengths much less than 40 msreduce efficiency and are not desired. Some call maintenance actionsrequire that the TSFD wireless handset 300 drop a voice frame. This maybe perceptible to the user but will be an infrequent occurrence. Thisapproach allows the TSFD wireless device to use only one transmitter toconserve size, weight, power consumption, and cost. A small amount ofin-band signaling data is available on the VDC, for example, DTMF(dual-tone multi-frequency) codes for digits dialed during a call, andcall progress codes including hangup indication. This in-band signalingdata is called “OH” for overhead data. 40 ms encoded voice frames arecompressed into a transmit window voice packet and transmitted from theTSFD wireless handset 300 with overhead data OH. The voice and overheadpackets are received as a received window voice packets by a TSFDwireless device and decompressed into 40 ms decoded voice frames. Thereverse of this process is being carried on by another TSFD wirelessdevice compressing and transmitting to the and TSFD wireless handset 300where the voice frame is decompressed and decoded by the TSFD wirelesshandset 300. All TSFD wireless devices, including the PNEs 800 and PS's600 are designed to use four channel Contiguous Channel AcquisitionProtocol (CCAP) data frames and packets between a TSFD wireless handset300 and another TSFD wireless device. 40 ms encoded voice frames arecompressed into a transmit window data packet, reviewed and overseen bythe PNE 800, which comprises four contiguous voice channels, andtransmitted from the TSFD wireless handset 300 with overhead data OH.The data and overhead packets are received as a received window datapackets by any TSFD wireless device and decompressed into 40 ms decodeddata frames. The reverse of this process is carried on by another TSFDwireless device compressing and transmitting to the TSFD wirelesshandset 300, TSFD wireless X-DatCom 400, TSFD wireless PC-DatCom Card500 and TSFD wireless ComDoc 900 where the data frame is decompressedand decoded. By using four contiguous voice channels to transmit data,the channel bandwidth is increased four-fold, or up to approximately 56kbps. This feature enables a laptop computer connected to any mobileTSFD wireless device to communicate at a 56 kbps rate with a desktopcomputer connected to a TSFD wireless ComDoc. Other communication pathsare also possible, such as a laptop connected to a TSFD wireless handset300 communicating via a TSFD wireless ComDoc and a PSTN 19 to anInternet 15 service provider. If twelve contiguous voice channels wereavailable to transmit data using a CCAP+ protocol; FIG. 10, the channelbandwidth may be increased twelve-fold, or up to approximately 250 kbps.The added bandwidths are obtained by adding adjacent channels togetherto obtain a higher data rate. Even more bandwidth is possible, thoughnot disclosed within this document.

In an additional embodiment of the present invention, it is significantto note that all CCAP or CCAP+ transmissions are provided “pathways”within the PNE's 800 domain by the PNE 800 on a Call Initiation Channel.The PNE 800 knows (keeps an active log), as does the Parallel ComputingArtificial Intelligence-base Distributive Call Routing System 1300-basedDistributive Routing System 1300, exactly which channels are adjacentand available. More significantly, when a CIC request is made from anyTSFD wireless device for any call, the PNE 800 makes a concerted effortto suggest grouping call channels fairly close together within eachwireless Transceiver (PNE's 800 and PSE 600's) microcell that handlesthe transfer of signals as to establish a section of the spectrum forthe possible transfer of data. This action by the PNE 800 is governed bymathematical models; algorithms, which detail the parameters of callchannel usage. To avoid encroaching upon existing calls, all TSFDwireless devices agree to use these suggestions for call routingprovided by the PNE 800. In creating the TSFD PNE 800 Reference ChannelFraming, a single, shared Reference Channel (RC) is used in eachmicrocell for broadcast to TSFD wireless handset 300 and TSFD wirelessComDocs 900, generated, initially, by the PNE 800. Four fixed physicalfrequencies from the microcell sub-band spectrum are allocated for theRC (i.e., uplink from TSFD wireless handset 300 to PSE 600, uplink fromPSE 600 to PNE 800, downlink from PNE 800 to PSE 600, and downlink fromPSE 600 to TSFD wireless handset 300), although the TSFD wirelesshandset 300, TSFD wireless ComDoc and TSFD wireless X-DatCom uplink isnot utilized. The TSFD wireless handset 300, TSFD wireless ComDocs 900,TSFD wireless PC-DatCom Cards 500 and TSFD wireless X-DatCom's read theRC to identify the presence of service. Without the RC, the TSFDwireless handset 300, TSFD wireless X-DatComs 400, TSFD wirelessPC-DatCom Cards 500 and TSFD wireless ComDocs 900 are inoperable. Thiseliminates the autonomous TSFD wireless devices from migrating into aservice where they are not licensed to operate. Besides identifyingwireless communication system service, the RC is used by the TSFDwireless handset 300, TSFD wireless ComDocs 900 and TSFD wirelessX-DatCom's to adjust their internal frequency reference (typically avoltage-controlled temperature-compensated crystal oscillator orVCTCXO). This adjustment capability allows the TSFD wireless device toachieve increased frequency accuracy and stability and thus improvedbit-error performance in demodulation of signals. The followinginformation (thought not limited to the information listed) is alsoprovided to the TSFD wireless handset 300, TSFD wireless ComDoc and TSFDwireless X-DatCom on the RC:

1. Date and Time

2. Microcell/Macrocell Identification Code

3. TSFD wireless handset 300/TSFD wireless ComDoc/TSFD wireless X-DatComAttention Codes (supports the CMC, described below)

4. Broadcast Text Messages

The PNE 800 also transmits special commands on the RC downlink that areaddressed to the PSE 600 rather than the TSFD wireless handset 300, TSFDwireless ComDocs 900 or TSFD wireless X-DatCom's. These commands areused to remotely enable/disable the PSE 600 and assign the microcelltype (which sets the frequency sub-blocks for use). Remote control ofthe microcell type provides system frequency agility. The RC uplink,while not used by the TSFD wireless handset 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900, isused by the PSE 600 for command acknowledgement and status reporting tothe PNE 800. There are 9 unique RC frequencies in the wirelesscommunication system, one for each microcell type. TSFD wireless handset300, TSFD wireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500 andTSFD wireless ComDocs 900 continually scan the RCs in order to identifythe TSFD wireless handset 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900microcell/macrocell location. This is accomplished by monitoring the RCpower levels and reading the microcell/macrocell ID codes. Real-timetracking of TSFD wireless handset 300 microcell location is importantfor mobile wireless communication because handoffs are required whenTSFD wireless handset 300 move between microcells. This feature couldalso apply to TSFD wireless ComDocs 900 and TSFD wireless X-DatComs 400,if they were to be relocated. In order to facilitate RC scanning while acall is active, TSFD wireless handset 300, TSFD wireless X-DatComs 400,TSFD wireless PC-DatCom Cards 500 and TSFD wireless ComDocs 900architecture includes two parallel receivers; one dedicated to the VDC,and the other dedicated to RC scanning. TSFD wireless handset 300, TSFDwireless ComDocs 900, TSFD wireless PC-DatCom 500 and TSFD wirelessX-DatCom's 400 receive functions are limited to about 50% duty factorwhen on a call. The length of the TSFD wireless handset 300, TSFDwireless X-DatComs 400, TSFD wireless PC-DatCom Cards 500 and TSFDwireless ComDocs 900 receive window is 20 ms based on the vocoder packetsize. At the system 16 kbps data rate, 20 ms amounts to 320 bits. Inorder for the TSFD wireless handset 300, TSFD wireless X-DatCom 400,TSFD wireless PC-DatCom Card 500 and TSFD wireless ComDoc 900 to ensurereceipt of a complete RC message, the message length must be less than ½of the TSFD wireless handset 300/TSFD wireless ComDoc or TSFD wirelessX-DatCom's receive window, or 10 ms, which amounts to 160 bits. In thiscase, for design purposes, the RC frame is limited to 150 bits. In orderto meet this size limitation, data may be distributed across multipleframes resulting in a superframe. For example, broadcast messages aredistributed across a superframe with only a few bytes in each frame.Each RC frame within the superframe is repeated four consecutive timesbefore advancing to the next frame; this is referred to as a block. Eachblock should be the same length as the 40 ms transmit/receive voiceframe. Repeating the RC frame transmission four times ensures that acomplete 10-ms RC frame will fall within the 20-ms TSFD wireless handset300/TSFD wireless ComDoc or TSFD wireless X-DatCom's receive window nomatter where the receive window begins within the 40-ms block.

Additional embodiment of the present invention follows: wherein the TSFDPNE 800 Dedicated Service Sub-Protocol (DSSP) is used; the TSFD PNE 800and all components within the TSFD system may be programmed to operatewithin a secure environment wherein the broadcasts of all systems andsub-systems are fully encrypted. Such operations could be utilized wherea TSFD network provided frequency hopping, encrypted communications;i.e., for military or government deployment. This form of communicationswould be extremely difficult to decode as the signals would not be“tagged’ with traditional message header information and would notremain on any given channel for any predictable time. Encryption andhopping algorithms would be changed rapidly by the PNE 800 and each TSFDwireless device would receive a code for determining the pattern.

The Parallel Computing Artificial Intelligence Computer-BasedDistributive Routing System

Turning now to FIG. 29 and FIG. 30, The Artificial Intelligence (AI)Computer Network is part of the Parallel Computing ArtificialIntelligence-based Distributive Routing System (PACI), 1300 which isresident, but decentralized in the TSFD wireless communication system.The system comprise a network of computers; FIG. 29 and FIG. 30, havingan AI computer residing in each PSE 600; wherein FIG. 29's numericaldesignators—1-21 define the AI computers, and each computer having anArtificial Intelligence software program to gather information regardingtimely calling data, routing and wireless device use histories and toanalyze the information for recommending or executing alternativecommunication paths within the entire system of the PSE 600 and the PNE800 during excessive peak hours loading of the PNE 800 or during acatastrophic failure of any PSE 600 or the PNE 800; see FIG. 29 and FIG.30. For example, the AI system learns by constantly polling all wirelessdevices for usage, polls the TSFD wireless ComDoc 900 several times aday and night to ask if the landline connected to it is in use andconstantly watches the PNE 800 to determine call loading and signs offailure. A limit may also be set on the number of calls that the PNE 800is handling that in turn triggers the Parallel Computing AI (PCAI)system to recommend to the system wireless sets with TSFD wirelessComDoc 900 use them or to PSEs 600 with dedicated TSFD wireless ComDoc900 and PSTN lines to take the load off the PNE 800. In a preferredembodiment, the limit is 95% capacity at the PNE 800. The informationobtained by the PCAI system can also be used to re-direct thecommunication paths to optimize call loads of the PSE 600 and PNE 800 inthe system, or to bypass any failed PSE 600 or PNE 800 in the system

The PCAI 1300 system may further report the day's gathered informationto each of the other PSE 600 for comparative analysis and making logicalsuggestions to the handsets 300, TSFD wireless X-DatComs 400, TSFDwireless PC-DatComs 500 and TSFD wireless ComDocs 900 operating withinthe system. The PC Artificial Intelligence System 1300 may further beprogrammed to gather relevant data from remotely placed external datacommunications modules by means of a wireless protocol established foroperations of the system. The wireless protocol is established foroperations of the system interfaced with a network including but notlimited to Public Switch Telephone Network 19 lines 800, a fiber opticcommunication link, a coaxial cable, a public TCP/IP network, adirectional emergency tower to tower microwave link, a satellitecommunication link, a communication docking bay routed to otherdestinations and data collection devices selected by the ArtificialIntelligence System.

In a further embodiment of the present invention, the PCAI 1300 systemfurther observes and administers the TSFD protocol during an activecatastrophic event in major TSFD Anchored Components. Within thispurview of methodologies, the PCAI 1300 system administers the TSFDProtocol which utilizes the PCS spectrum as illustrated in FIG. 5. ThePCS low band is reserved for PSE 600 receive frequencies, and the highband for PSE 600 transmit frequencies. Half of each band is reserved forsignals between the PSEs 600 and the TSFD wireless handsets 300, betweenPSE's 600 and TSFD wireless ComDocs 900, or between PSE 600 and TSFDwireless X-DatComs 400 with the other half for signals between the PSEs600 and the PNE 800. Regarding the wireless communications systemdepicted in FIG. 5, a TSFD wireless ComDoc 900 communicates with a PSE600 in the same manner that a TSFD wireless handset 300 communicateswith a PSE 600 and an TSFD wireless X-DatCom 400 also communicates witha PSE 600 in the same manner that a TSFD wireless handset 300communicates with a PSE 600. With duplex filtering and 80-MHz separationbetween the low band and high band; as described in FIG. 4 & FIG. 5, thePSE 600 can simultaneously receive and transmit signals withoutcompromising receiver sensitivity. This frequency plan, alsoadministered by the PCAI during catastrophic failures, allows calls totake place asynchronously, which simplifies the design. Although, manypossible timing architectures may be used in the present wirelesscommunication system, an asynchronous system architecture was selectedto provide the best fit to the key requirements of cost, range, userdensity and human limitations to perceptibility of delayed audio signalswithin the TSFD Protocol network. Asynchronous operation of the presentwireless communication system allows greater flexibility in systemgeographic layout, simpler digital protocol, and channel separationstructure. Conventional digital cellular and PCS systems are designedsuch that synchronous operation is a necessity. CDMA cellular/PCSsystems require synchronous operation to insure demodulation and precisecoordination of power control and TDMA cellular/PCS systems requiresynchronous operation to prevent time slot interference. Synchronousoperation allows the system design to make very efficient use of theassigned spectrum (high user density) for a given size geographic areafor a trade-offs in system complexity, cost, flexibility and limits onrelaying signals within a cell site's control. The present wirelesscommunication system has lower density requirements (rural environment),so the advantages of asynchronous operation became very beneficial tothe required cost effectiveness 800 of the present system design. Humanphysiology is unable to detect delays in an audio signal of up to 80milliseconds. Advantages of this asynchronous operation becomes verybeneficial when sending signals from PSE 600 to PSE 600 over greatdistances that approach this 80 millisecond human threshold ofdetectability. Estimates by wireless engineers are in excess of 1,000miles for the relaying of voice signals within this asynchronous systembefore the user becomes aware of a delay in the audio. No synchronousPCS system can even approach distances as great as 27 miles whenrelaying/repeating audio signals within a given cell tower's control;restricted by the speed of light and the absolute requirement to staysynchronized with the tower from which the audio signal derived and inwhich the TSFD wireless handset 300 is registered operationally. FIG. 5also shows how the PCS bands are further divided into sub-bandsdedicated for each of the 9 microcell types. Each microcell uses thesub-bands assigned for its particular type (alpha-numeric designator A1,A2, A3, B1, B2, B3, C1, C2, or C3) in order to preclude interferencewith adjacent microcells (since adjacent microcells are never of thesame type). The microcell sub-bands are 825 kHz wide for PCS blocks ABC,and 275 kHz wide for blocks DEF. The definition of 9 microcell typesprovides two additional non-adjacent types beyond the minimum 7 that arerequired for a hexagonal cell layout with FDMA shown in FIG. 3. For amicrocell in the cell pattern illustrated in FIG. 3, the additional twonon-adjacent types are the other two alpha designators with the samenumeric designator. For example, the sub-bands for microcell types A2and C2 are not used in the microcells adjacent to microcell B2.Sub-bands A1ML, A2ML, A3ML, B1ML, B2ML, B3ML, C1ML, C2ML and C3ML areassigned to communication from a TSFD wireless handset 300, a TSFDwireless PC-DatCom Card, a TSFD wireless ComDoc 900 or an TSFD wirelessX-DatCom 400 to a PSE 600. Sub-bands A1MH, A2MH, A3MH, B1MH, B2MH, B3MH,C1MH, C2MH and C3MH are assigned to communication from a PSE 600 to aTSFD wireless handset 300, a TSFD wireless PC-DatCom Card, a TSFDwireless ComDoc 900 or an TSFD wireless X-DatCom 400. Sub-bands A1XL,A2XL, A3XL, B1XL, B2XL, B3XL, C1XL, C2XL and C3XL are assigned tocommunication from a PNE 800 to a PSE 600. Sub-bands A1XH, A2XH, A3XH,B1XH, B2XH, B3XH, C1XH, C2XH and C3XH are assigned to communication froma PSE 600 to a PNE 800.

Again within a catastrophic failure, the PCAI system administers theTSFD system controlling PSE 600 power amplifier gains of the three RFpaths (uplink, downlink, local), independently adjusting the system, asneeded, in 3 dB steps over a 60 dB range from 37 to 97 dB. The gainadjustments are usually made manually during installation based on themicrocell size. The PCAI system takes the place of human or meremechanical intervention.

In another embodiment of the present invention, The Parallel ComputingArtificial Intelligence (AI) Computer Network is presented in FIG. 29and FIG. 30; wherein the Parallel Computing Artificial Intelligence (AI)Computer Network 1300 is part of the Parallel Computing ArtificialIntelligence-based Distributive Routing System 1300 which is residentbut decentralized over the entire the system. The system comprises anetwork of computers having a computer residing in each PSE, see FIG. 20and FIG. 21, and each computer having an Parallel Computing ArtificialIntelligence software program to gather information regarding timelycalling data, routing and wireless device use histories and to analyzethe information for recommending or executing alternative communicationpaths within the entire system of the PSEs 600 and the PNE 800 duringexcessive peak hours loading of the PNE or during a catastrophic failureof any PSE or the PNE. For example, the AI system learns by constantlypolling all wireless devices for usage, polls the TSFD wireless ComDocs900 several times a day and night to ask if the landline connected to itis in use and constantly watches the PNE to determine call loading andsigns of failure. A limit may also be set on the number of calls thatthe PNE 800 is handling that in turn triggers the AI system 1300 torecommend to the system wireless sets with TSFD wireless ComDocs 900 usethem or to PSEs with dedicated TSFD wireless ComDocs 900 and PSTN linesto take the load off the PNE. In a preferred embodiment, the limit is95% capacity at the PNE. The information obtained by the AI system canalso be used to re-direct the communication paths to optimize call loadsof the PSEs 600 and PNEs 800 in the system, or to bypass any failed PSEs600 or PNEs 800 in the system.

The AI system 1300 may further report the day's gathered information toeach of the other PSEs 600 for comparative analysis and making logicalsuggestions to the TSFD wireless handsets 300, communications dockingbays and External Data Communications Modules operating within thesystem. The Parallel Computing Artificial Intelligence System mayfurther be programmed to gather relevant data from remotely placedexternal data communications modules by means of a wireless protocolestablished for operations of the system. The wireless protocol isestablished for operations of the system interfaced with a networkincluding but not limited to four Public Switch Telephone Network 19lines, a fiber optic communication link, a coaxial cable, a publicTCP/IP network, a directional emergency tower to tower microwave link, asatellite communication link, a communication docking bay routed toother destinations and data collection devices selected by the ParallelComputing Artificial Intelligence System.

In an alternate embodiment, the Parallel Computing ArtificialIntelligence-Based Distributive Routing for Time-Shared Full DuplexWireless System's Physical Hardware, Resources required and DataVariables are defined:

-   -   1. TSFD Wireless TSFD wireless handsets 300    -   2. TSFD Wireless TSFD wireless ComDoc 900    -   3. TSFD Wireless TSFD wireless X-DatComs 400    -   4. TSFD Wireless Personal Computer Cards    -   5. TSFD Wireless PSEs 600    -   6. TSFD Wireless PNE 800    -   7. TSFD Dedicated Wirelines    -   8. TSFD Dedicated Fiber Optic Lines    -   9. TSFD Dedicated Microwave Links    -   10. TSFD Dedicated Optical Laser Links    -   11. TSFD Dedicated Satellite Links    -   12. TSFD Customer Database    -   13. TSFD Customer Database Internet Storage Address

In additional disclosure of the present invention, Spatials areconsidered by the AI System for making accurate decisions:

-   -   1. Time of Day    -   2. Time Zone    -   3. Day    -   4. Month    -   5. Year    -   6. GPS Code    -   7. Geographic Location    -   8. Location of TSFD Wireless TSFD wireless handset during a        Distress Call    -   9. Location of PSE's    -   10. Location of PNE's    -   11. Location of TSFD Wireless TSFD wireless handsets 300 during        Operation    -   12. Location of TSFD wireless ComDoc 900 during Operation    -   13. Location of TSFD wireless X-DatCom during Operation

The present invention requires the AI system to consider FirmDeterminants necessary to make comprehensive decisions:

-   -   1. Length of “Air-Time” on Customer Contract    -   2. Status of Customer Billing    -   3. Status of Equipment-Go/No-Go    -   4. PNE 800 Electrical Power    -   5. PSE Electrical Power    -   6. Internet Interface Availability for PNE 800    -   7. PSTN Interface Lines Availability    -   8. Satellite Link Availability    -   9. TSFD wireless handsets 300-TSFD wireless ComDoc 900-TSFD        wireless X-DatComs 400 Availability to Receive a Call

Variables within the TSFD wireless system which the AI System mustconsider:

-   -   1. Length of Call by Each Customer    -   2. Length of Time PNE 800 “Manages” a Call    -   3. Length of Time a PSE “Extends” a Call    -   4. Length of Time Needed to Complete a Call    -   5. Length of Time Needed to Locate a Customer-Emergency 911    -   6. Length of Time Allocated to a billed Customer    -   7. Length of Time Allocated to a Prepaid Customer    -   8. Length of Time Spent Sending or Receiving TSFD wireless        X-DatCom Data    -   9. Size of Customer Database    -   10. Duplication Rules for a Customer Database-backup    -   11. Calls Completed Within PSE Domain Only    -   12. Calls Routed Through PSE-TSFD wireless ComDoc 900-Landline    -   13. Calls Routed Through PSE-PNE-PSTN Interface    -   14. Calls Routed Through PSE-PNE-Internet Interface    -   15. Calls Routed Through PSE-PNE-PSE-TSFD Wireless Device    -   16. Calls Routed Through PSTN to TSFD Network

Further describing the AI system's attributes, the TSFD Systems InternalSoftware enabled for AI Interactions are disclosed:

-   -   1. TSFD Wireless TSFD wireless handset Internal Software    -   2. TSFD Wireless TSFD wireless ComDoc 900 Internal Software    -   3. TSFD Wireless TSFD wireless X-DatCom Internal Software    -   4. TSFD Wireless Personal Computer Card Internal Software    -   5. TSFD Wireless PSE Internal Software    -   6. TSFD Wireless PNE 800 Internal Software    -   7. TSFD Wireless Locator—911 Distress Software-PNE    -   8. TSFD Wireless Locator—911 Distress Software-PSE    -   9. PNE 800—Computer Internet Customer Billing Software    -   10. Anti-Hacker TSFD Systems Security Software

Plots of relevant factors and data from which the AI system must drawconclusions and make logical deductions:

-   -   1. Map of Calling Patterns within a PNE 800 Domain    -   2. Subset Maps of Calling Patterns within Individual PSE Domains    -   3. Map of Calling Patterns to External Networks via the PNE    -   4. Map of Calling Patterns to External Networks via the        PSE-Dedicated TSFD wireless ComDoc 900    -   5. Map of Calling Patterns to External Networks via Subscriber        TSFD wireless ComDoc 900    -   6. Map of Known Distress Calls and PSE's Responsible for        Response

In an alternate illumination of the present invention, General TSFD-AIOperational Assumptions are disclosed: the TSFD Parallel ComputingArtificial Intelligence-based Distributive Routing System 1300 will useup to 22 PC's within a Macrocell, parallel computing and analyzing data.Various levels of “override” control of the TSFD Macrocell functionalityby the AI System only occurs wherein there are failures of the physicalTSFD hardware (PSE's or the PNE) or failure of the proprietary TSFDrouting software inherent in the PNE 800.

Judgments made by the TSFD Parallel Computing ArtificialIntelligence-based Distributive Routing System 1300 are based entirelyon preset parameters for the following (though not every possibleparameter can be presented):

-   -   1. TSFD Network system operations (known values for TSFD        hardware electronic test point levels)    -   2. preset parameters for TSFD Network system subscriber wireless        device calling loads at the PNE 800    -   3. preset parameters for TSFD Network system subscriber wireless        device calling loads at each PSE    -   4. preset parameters for TSFD Network system subscriber call        distributions over specific and available PSE channels-reserving        room for CCAP & CCAP+ Data Transfers and IDDT live video        streaming    -   5. preset parameters for TSFD Network system subscriber call        distributions over specific and available PNE 800 channels    -   6. preset parameters for TSFD Network system subscriber call        distributions to specific and available PNE 800-PSTN Interface        lines.

In a further embodiment of the present invention, technical Disclosuresof the Parallel Computing Artificial Intelligence-based System: Thegeneral concept of a Parallel Computing Artificial Intelligence-basedDistributive Routing System 1300 is one of an “oversight entity” keepingtrack of every possible transaction performed within a TSFD MacrocellNetwork. This system would generate operational models, virtual maps,flow charts, electronic component diagnosis reports, and efficiencyreports. Further, the AI System would “take over” the functions of a PNE800, i.e., wherein the PNE had failed and call routing had to beperformed across the numerous PSEs 600 individually, composing a TSFDMacrocell. Armed with detailed functionality and operational historiesof every TSFD subsystem and wireless device ever operated within thenetwork, the AI virtual entity would perform extensive logic deductions,thereby generating systematic and logical courses of actions best suitedto TSFD system conditions and the ultimate satisfaction of the TSFDNetwork subscriber. The specific Parallel Computing ArtificialIntelligence-based software to perform these actions is commerciallyavailable, but must be extensively adapted to TSFD Network conditions.This AI System would also be suitable to perform electronic componentmonitoring-reporting, defined systems analysis, Erlong evaluations andprescribed measurements within synchronous wireless systems, i.e., thosecomposed of traditional base stations and the occasional PCS stylerepeater.

In an alternate embodiment; Parallel Computing ArtificialIntelligence-based Distributive Routing 1300 and the Virtual MacrocellLAN; FIG. 29: the Parallel Computing Artificial Intelligence-basedDistributive Routing System 1300 is composed of a group of computers ofthe Personal Computer style, industrial grade, with superior featuresand performance linked together by a dedicated Local Area Network (LAN);illuminated in FIG. 28. The primary computer in the group would residenear, but not within, a PNE 800, with all other computers residing inthe electronic component environmental housing of each PSE. All unitswould share information and be programmed to operate as a single“entity” via the TSFD LAN. Any single computer could be disconnected andthe system would still function. The term “parallel computing” would bean operational function of the system, wherein a task could bedistributed at the same time to several units for analysis. Failure ofanalysis would then be less likely since the transactions would becomputed in “parallel”. Resulting data (answers to the transaction)would be utilized by the first system to complete the task. The actionof watching every TSFD Wireless Network transaction would not includelistening to the content of each data transmission or phone call.However, this feature would be available on systems sold to thegovernment or military and could include biometric analysis of caller'strue identity and corresponding speech recognition patterns.

In another embodiment of the invention FIG. 32 illuminates the ParallelComputing Artificial Intelligence-based Distributive Routing and the Ina further embodiment; Virtual Macrocell WAN, wherein; The ParallelComputing Artificial Intelligence-based Distributive Routing System 1300is composed of a group of computers; FIG. 30 wherein the Alphadesignators indicate the primary macrocell AI computers, of the PersonalComputer style, industrial grade, with superior features and performancelinked together by a dedicated Wide Area Network (WAN). This networkconsists of multiple Macrocells linked in a Wide Area Network (WAN)wherein each PNE's 800 Parallel Computing Artificial Intelligence-basedDistributive Routing computer network is linked to other such PNE 800systems. The purpose of this WAN is the exchange of information duringcatastrophic failures or for the gathering of extensive, WAN wide datato determine the most effective operation of linked AI Systems governingspecific networks.

Further, such a WAN analysis would yield informative data for futuresystems.

A further embodiment of this invention describes functionality unknownin any other wireless technology, i.e., the control of major wirelesssystems, subsystems, and individual devices when utilizing carefullycontrolled, coded or encrypted access. Static State Control by the AISystem:

-   -   1. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Static        State Control of any TSFD wireless handset via the TSFD Network.    -   2. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Static        State Control of any TSFD wireless ComDoc 900 via the TSFD        Network.    -   3. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Static        State Control of any TSFD wireless X-DatCom via the TSFD        Network.    -   4. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Static        State Control of any TSFD PC Laptop Wireless Cards; i.e. TSFD        wireless PC-DatCom Cards 500, via the TSFD Network.    -   5. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of any TSFD        PC Laptop Wireless Cards; i.e. TSFD wireless PC-DatCom Cards        500, via the TSFD Network.    -   6. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of a PC        Home Computer via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   7. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of a cable        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless ComDoc 900 peripheral interface        connections.    -   8. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of a        PSTN/DSL modem for access by a specific TSFD wireless device to        the Internet via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   9. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of a LAN        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless ComDoc 900 peripheral interface        connections.    -   10. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless ComDoc 900 peripheral interface connections.    -   11. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        ComDoc 900 peripheral interface connections.    -   12. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of an        Infrared Data Sensor via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   13. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Static State Control of an        External Video Camera via the TSFD wireless ComDoc 900        peripheral interface connections.    -   14. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a PC Home        Computer via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   15. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of any or all        TSFD PC Laptop Wireless Cards; i.e. TSFD wireless PC-DatCom        Cards 500, via the TSFD Network.    -   16. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a cable        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   17. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a PSTN/DSL        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   18. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a LAN        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   19. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   20. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   21. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   22. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Static State Control of an        External Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   23. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP's internal        Memory.    -   24. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE housing or by such portable data storage medium as will        facilitate uploading new data control instructions when inserted        in the PNECP's data drives.    -   25. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the TSFD Network.    -   26. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by programming        instructions received by transmissions from remotely located        TSFD Network authorized personnel via the PSTN, the Internet,        direct copper connections using DS-1 connections, direct fiber        connections using OC-3 links, radio links with the DS-1        hardware, an Earth-Satellite ground station for direct two-way        communications with telecom satellites, the sending and        receiving of short haul, ultra-wide-band optical communications        via modulated Laser links.    -   27. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by transmissions        from the Parallel Computing Artificial Intelligence-based        Distributive Routing Computer located within the Environmental        Housing of the PNE 800.    -   28. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Static State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges during a        catastrophic failure within the TSFD Network.        Dynamic State Control by the AI System:    -   1. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Dynamic        State Control of any TSFD wireless handset via the TSFD Network.    -   2. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Dynamic        State Control of any TSFD wireless ComDoc 900 via the TSFD        Network.    -   3. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Dynamic        State Control of any TSFD wireless X-DatCom 400 via the TSFD        Network.    -   4. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to exercise Dynamic        State Control of any TSFD PC Laptop Wireless Cards; i.e. TSFD        wireless PC-DatCom Cards 500, via the TSFD Network.    -   5. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of any        TSFD PC Laptop Wireless Cards; i.e. TSFD wireless PC-DatCom        Cards 500, via the TSFD Network.    -   6. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of a PC        Home Computer via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   7. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of a cable        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless ComDoc 900 peripheral interface        connections.    -   8. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of a        PSTN/DSL modem for access by a specific TSFD wireless device to        the Internet via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   9. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of a LAN        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless ComDoc 900 peripheral interface        connections.    -   10. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless ComDoc 900 peripheral interface connections.    -   11. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of a        CD/DVD Drive for the retrieval of digital data via the TSFD        wireless ComDoc 900 peripheral interface connections.    -   12. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of an        Infrared Data Sensor via the TSFD wireless ComDoc 900 peripheral        interface connections.    -   13. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command a TSFD        wireless ComDoc 900 to exercise Dynamic State Control of an        External Video Camera via the TSFD wireless ComDoc 900        peripheral interface connections.    -   14. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of a cable        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   15. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of any or        all TSFD PC Laptop Wireless Cards; i.e. TSFD wireless PC-DatCom        Cards 500, via the TSFD Network.    -   16. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of a        PSTN/DSL modem for access by the TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   17. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of a LAN        modem for access by a specific TSFD wireless device to the        Internet via the TSFD wireless X-DatCom's optional peripheral        interface connections.    -   18. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of an        External Hard Drive for the retrieval of digital data via the        TSFD wireless X-DatCom's optional peripheral interface        connections.    -   19. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of a CD/DVD        Drive for the retrieval of digital data via the TSFD wireless        X-DatCom's optional peripheral interface connections.    -   20. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of an        Infrared Data Sensor via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   21. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300 is used to command an TSFD        wireless X-DatCom to exercise Dynamic State Control of an        External Video Camera via the TSFD wireless X-DatCom's optional        peripheral interface connections.    -   22. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by predetermined        and defined software parameters stored in the PNECP's internal        Memory.    -   23. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor (PNECP); wherein        the PNCEP is composed of PNE Central Processors 830 a & 830 b        comprising a whole and complete PNE Central Processor system, to        exercise Dynamic State Control over the Subscriber Database,        located on a website on the Internet, containing all TSFD        wireless handsets 300, TSFD wireless ComDoc 900 TSFD wireless        X-DatComs 400 and TSFD wireless PC-DatCom Cards 500 for        activation, deactivation and billing privileges by external        instructions from a keypad, touch-active video screen within the        PNE housing or by such portable data storage medium as will        facilitate uploading new data instructions when inserted in the        PNECP's data drives.    -   24. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor to exercise        Dynamic State Control over the Subscriber Database, located on a        website on the Internet, containing all TSFD wireless handsets        300, TSFD wireless ComDoc 900 TSFD wireless X-DatComs 400 and        TSFD wireless PC-DatCom Cards 500 for activation, deactivation        and billing privileges by programming instructions received by        transmissions from remotely located TSFD Network authorized        personnel via the TSFD Network.    -   25. A Parallel Computing Artificial Intelligence-based        Distributive Routing System 1300, via a secure access code, may        be used to instruct the PNE Central Processor to exercise        Dynamic State Control over the Subscriber Database, located on a        website on the Internet, containing all TSFD wireless handsets        300, TSFD wireless ComDoc 900 TSFD wireless X-DatComs 400 and        TSFD wireless PC-DatCom Cards 500 for activation, deactivation        and billing privileges by programming instructions received by        transmissions from remotely located TSFD Network authorized        personnel via the PSTN, the Internet, direct copper connections        using DS-1 connections, direct fiber connections using OC-3        links, radio links with the DS-1 hardware, an Earth-Satellite        ground station for direct two-way communications with telecom        satellites, the sending and receiving of short haul,        ultra-wide-band optical communications via modulated Laser        links.        Monocell System

In a distinct and alternate embodiment of the present invention, thesatellite ground station interface can enable a single PSE 600 tooperate virtually in an autonomous mode when the entire system ispowered by a solar cell or wind electrical power system. Such a systemis known as the PSE-Monocell. This operation could provide a modernwireless communications system for some remote village where no othertelephonic communication is available or an extremely remotecommercial/industrial outpost. The TSFD wireless devices in the villagecould be recharged by an alternate energy source, such as but is notlimited to solar cells, and communication between device owners would beenabled by the PSE 600 (the central relay point in the system), withoutany PNE 800 whatsoever. Call routing and determinations of frequencypair availability would clearly be in the operational purview of everyTSFD wireless device. These autonomous devices would merely poll a setof frequencies to determine availability and then place the call via theCIC, completing the call via the CMC wherein the assigned channel pairswould be agreed upon by each TSFD wireless device.

Calls outside the TSFD wireless system via a satellite ground stationcould easily be assigned to a set of channels reserved for suchtransactions with a simple version of the Parallel Computing ArtificialIntelligence-based Call Routing (small PC embedded within the PSE 600)enabling the PSE 600 to mimic a fully functional PNE 800 with “ExternalNetwork Interface” capabilities through dedicated wireless TSFD wirelessComDoc interfaces. Actual external interface connections would not existand would be achieved wirelessly by the attachment of TSFD wirelessComDoc 900 devices to the external networks, radios or satellite earthstations. GPS monitoring by the PSE 600 as the primary method offrequency/channel stability would be essential. Such systems would beextremely inexpensive and highly reliable.

The monocell wireless system may further comprise a Parallel ComputingArtificial Intelligence-based Call Routing system to monitor and analyzecommunication paths within and system and to allow the PSE to mimic thefunction of a PNE. External interface connections to an external networkcan be achieved wirelessly via a TSFD wireless ComDoc attached to theexternal network. The monocell system may include a method forcollecting revenue from each wireless set operating within the monocellsystem. Examples of methods for collecting revenue are disclosed in U.S.Pat. Nos. 6,141,531 and 6,842,617. In another embodiment, the monocellwireless system allows transmission in the CCAP or CCAP+ sub-protocolfrom one wireless device to another wireless device within the monocellsystem. In yet another embodiment, the monocell system can be controlledremotely by another wireless device outside the system via a satellite.In a further embodiment, the wireless devices in the monocell system canbe remotely controlled by another wireless device outside the system viaa satellite. Examples of methods to control the system or a wirelessdevice in the system are disclosed in U.S. Pat. Nos. 6,374,078 and6,842,617.

Additional Terms and Definitions

To further disclosure and illuminate aspects of the present invention,the following Additional Terms and Definitions of the TSFD wirelesssystem are described:

-   -   1. PolyCons    -   2. Red Fang Protocol    -   3. Migrated Channel Data    -   4. Fuzzy Switch Logic    -   5. PolyPath    -   6. MonoCell    -   7. Dynamic Network Expansion    -   8. Integrated Direct Data Transfer (IDDT    -   9. PolySets    -   10. Domains    -   11. Mobile Devices    -   12. Anchored Systems    -   13. Digital Image Capture or Stereoscopic Direct Data Transfer

1. PolyCon is a term defined as the multiple (poly) communicationsavenues available to all independent and autonomous TSFD wirelessdevices within a TSFD network or externally. Example: A TSFD wirelessComDoc 900 is said to have seventeen PolyCons. A TSFD wireless X-DatCom400 is said to have an unknown number of PolyCons available. (We just donot know what all this device can be attached to or just how many ofthese hookups are possible.)

2. Red Fang Protocol is an Ultra-Wide Band—Ultra Low Power version ofthe TSFD Protocol operated at 5 Gigahertz. Bandwidth can be varied asnecessary and generally communications are limited to 3 feet distancewith line of sight as the optimum operating mode.

3. Migrated Channel Data is that data transmitted over the TSFD networkthat is subjected to frequency hopping for security.

4. Fuzzy Switch Logic: An “AI” term to describe the actions of the AIsystem 1300 in making a firm decision from a number of reasonablechoices.

5. PolyPath: Multiple alternate routes suggested by the AI system 1300for routing calls around a failed TSFD component. As “AI” term; “FuzzyLogic” rules would determine which “suggestion” to be chosen andimplemented. Example: the permutations of “Moves on a chessboard”.

6. MonoCell System is a TSFD cell site that can stand alone for thecoverage of a small town, village or rural area where no otherconnection is made to another cell site. The MonoCell can be connectedvia fiber or earth satellite to the rest of the world wirelessly viadedicated TSFD wireless ComDocs 900 but is not a part of any other cellsite. The site can handle very few to several hundred TSFD wirelesshandsets. The site has no PNE requirements. This site is totally poweredby solar, wind or a combination. The system is essentially a whollyautonomous and sophisticated PSE 600.

7. Dynamic Network Expansion: The process of adding more PSE's 800 to aMacrocell.

8. Integrated Direct Data Transfer: the term describing the continuousflow of data over the TSFD network during a CCAP or CCAP+ data transferthrough the activation of a temporary TSFD Sub-Protocol routine within astandard TSFD transmission; FIG. 11. The IDDT sub-protocol is dynamic asthe bandwidth utilized may be varied.

9. PolySets are multiple but distinct data analysis results created bydifferent “parallel processing” PC's; FIG. 29, where each has been givena task to analyze overall Macrocell data. It will be rare to havevarying results but it could be possible. The fastest computer winsunless its data differs from all the others. At that point, another taskis assigned without the winning computer being included. A primarycomputer; the PNE AI computer, performs the selections of these PolySetsolutions. Major variations could be attributed to the usage of AIalgorithms differing from other PC's. Applications include analysis oftraffic patterns of call loading, peak usage, off network access by TSFDdevices, etc.

10. Domains are defined as the area of influence a TSFD Anchored Systeminfluences or controls; i.e., approximately 114 square miles comprisesthe domain of the average TSFD PSE 600.

11. Mobile TSFD wireless devices are defined as the following TSFDwireless devices; TSFD wireless handsets 300, TSFD wireless X-DatComs400, TSFD wireless PC-DatCom Cards, and TSFD wireless ComDocs.

12. Anchored TSFD Systems are defined as TSFD PNEs 800 and TSFD PSEs 600wherein their locations are immovable and fixed.

13. Digital Image Capture or Stereoscopic Direct Data Transfer and livevideo streaming; wherein the various Mobile TSFD wireless devices can beequipped with a pair of digital cameras enabling the devices to captureor to send still, live, recorded video images or stereoscopic livedigital images for recovery by another TSFD wireless device wherein avirtual reality stereoscopic display viewer has been attached.

Although the present invention has been described in detail withreference to certain preferred embodiments, it should be apparent thatmodifications and adaptations to those embodiments may occur to personsskilled in the art without departing from the spirit and scope of thepresent invention as set forth in the following claims.

While specific embodiments have been illustrated and described, numerousmodifications come to mind without departing from the spirit of theinvention and the scope of protection is only limited by the scope ofthe accompanying claims.

1. A method of operating a parallel-configured Time-Shared Full Duplex(TSFD) wireless communication system for voice and data signals, thesystem comprising one or more macrocells and each macrocell having aplurality of microcells and the method comprises: establishing a localcommunication path for transmitting and receiving signals between alocal TSFD wireless device and a remotely placed local TSFD wirelessdevice within a same microcell via a Parallel-configured Signal Extender(PSE); operating the PSE by operating first and second signal extendersin parallel and independent of each other yet sharing information witheach other and upon failure of one of the first and second signalextenders the other one of the first and second signal extenderscontinues operation and maintains communications; establishing anextended communication path for transmitting and receiving signalsbetween an extended TSFD wireless device and a remotely placed extendedTSFD wireless device located within different microcells positionedwithin a same macrocell via PSEs and a Parallel-configured NetworkExtender (PNE); operating the PNE by operating first and second networkextenders in parallel and independent of each other yet sharinginformation with each other and upon failure of one of the first andsecond network extenders the other one of the first and second networkextenders continues operation and maintains communications; establishinga distant communication path for transmitting and receiving signalsbetween a distant TSFD wireless device and a remotely placed distantTSFD wireless device located within different microcells positionedwithin different macrocells via PSEs and PNEs; asynchronouslytransmitting and receiving half-duplex signals over the communicationpaths using pairs of assigned communication path frequencies stabilizedby a GPS-based frequency reference source; monitoring and analyzing thecommunication paths by a system-resident and decentralized ParallelComputing Artificial Intelligence-based Distributive Routing System; andre-directing the communication paths to ensure call loads of the PSE andPNE in the system do not exceed a predetermined limit for each PSE orPNE, to optimize call loads of the PSE and PNE in the system, or tobypass any failed PSE or PNE in the system; wherein the TSFD wirelessdevice is selected from the group consisting of TSFD wireless handsets,TSFD wireless Personal Computer Data Communication Cards (TSFD wirelessPC-DatCom Cards), TSFD wireless Data Communication Modules (TSFDwireless DatComs), and TSFD wireless Communication Docking Bays (TSFDwireless ComDocs), and wherein the transmitting and receiving signalsbetween a TSFD wireless device or PSE or a PNE and another TSFD)wireless device or a PSE or PNE is conducted asynchronously with aprimary Time-Shared Full Duplex (TSFD) wireless protocol.
 2. The methodof claim 1 wherein establishing a local communication path comprises:transmitting signals from the local TSFD wireless devices to the PSE;receiving and re-transmitting signals by the PSE to the local TSFDwireless devices; and receiving signals from the PSE by the local TSFDwireless devices.
 3. The method of claim 1 wherein establishing anextended communication path comprises: transmitting signals from theextended TSFD wireless devices to the PSE; receiving and re-transmittingsignals from the extended TSFD wireless devices by the PSE to a PNE;receiving and re-transmitting signals from the PSE by the PNE to thePSE; receiving and retransmitting signals from the PNE by the PSE to theextended TSFD wireless devices; and receiving signals from the PSE bythe extended TSFD wireless devices.
 4. The method of claim 1 whereinestablishing a distant communication path comprises: transmittingsignals from the distant TSFD wireless devices to the PSEs; receivingand re-transmitting signals from the distant TSFD wireless devices bythe PSEs to the PNEs; receiving and re-transmitting signals from thePSEs by a PNE to another PNE; receiving and re-transmitting signals froma PNE by another PNE to PSEs; receiving and re-transmitting signals fromPNEs by PSEs to the distant TSFD wireless devices; and receiving signalsfrom PSEs by the distant TSFD wireless devices.
 5. The method of claim 4wherein receiving and re-transmitting signals by a PNE to another PNE isselected from the group consisting of transmitting signals over a PublicSwitch Telephone Network (PSTN), transmitting signals over a fiber opticcommunication link, transmitting signals over a coaxial cable,transmitting signals over a public TCP/IP network, and transmittingsignals over a satellite communication link,
 6. The method of claim 1wherein half of the signals received by a PSE in a microcell may betransmitted by TSFD wireless devices in the microcell in a low radiofrequency band and half of the signals received by the PSE in amacrocell may be transmitted by a PNE in the macrocell in a low radiofrequency band.
 7. The method of claim 1 wherein half of the signalstransmitted by a PSE in a microcell may be received by a TSFD wirelessdevice in the microcell in a high radio frequency band and half of thesignals transmitted by the PSE in a macrocell may be received by a PNEin the macrocell in a high radio frequency band.
 8. The method of claim1 wherein establishing a local voice communication path between a localTSFD wireless device and a remotely placed local TSFD wireless devicecomprises using two fixed frequencies in a sub-band spectrum forestablishing a local voice channel.
 9. The method of claim 1 whereinestablishing a local data communication path under a four channelContiguous Channel Acquisition Protocol between a local TSFD wirelessdevice and a remotely placed local TSFD wireless device comprises usingtwo fixed frequencies having a bandwidth of four times the bandwidth ofa local voice channel by combining four contiguous voice channels. 10.The method of claim 1 wherein establishing a local data communicationpath under a twelve channel Contiguous Channel Acquisition Protocol Plusbetween a local TSFD wireless device and a remotely placed local TSFDwireless device under a twelve channel Contiguous Channel AcquisitionProtocol Plus comprises using two fixed frequencies having a bandwidthof twelve times the bandwidth of a local voice channel by combiningtwelve contiguous voice channels.
 11. The method of claim 1 whereinestablishing an extended voice communication path comprises using fourfixed frequencies in a sub-band spectrum for establishing an extendedvoice channel.
 12. The method of claim 1 wherein establishing anextended data communication path under a four channel Contiguous ChannelAcquisition Protocol between an extended TSFD wireless device and aremotely placed extended TSFD wireless device comprises using four fixedfrequencies having a bandwidth of four times the bandwidth of anextended voice channel by combining four contiguous voice channels. 13.The method of claim 1 wherein establishing an extended datacommunication path under a twelve channel Contiguous Channel AcquisitionProtocol Plus between an extended TSFD wireless device and a remotelyplaced extended TSFD wireless device comprises using four fixedfrequencies having a bandwidth of twelve times a bandwidth of anextended voice channel by combining twelve contiguous voice channels.14. The method of claim 1 wherein establishing a distant voicecommunication pat comprises using four fixed frequencies in a sub-bandspectrum for establishing a distant voice channel.
 15. The method ofclaim 1 wherein establishing a distant data communication path under afour channel Contiguous Channel Acquisition Protocol between a distantTSFD wireless device and a remotely placed distant TSFD wireless devicecomprises using four fixed frequencies having a bandwidth of four timesthe bandwidth of a distant voice channel by combining four contiguousvoice channels.
 16. The method of claim 1 wherein establishing a distantdata communication path under a twelve channel Contiguous ChannelAcquisition Protocol Plus between a distant TSFD wireless device and aremotely placed distant TSFD wireless device comprises using four fixedfrequencies having a bandwidth of twelve times a bandwidth of a distantvoice channel by combining twelve contiguous voice channels.
 17. Themethod of claim 1 further comprises establishing a communication pathfor transmitting and receiving signals between a TSFD wireless deviceand an external network via a PSE and a PNE connected to the externalnetwork.
 18. The method of claim 17, wherein the external network isselected from the group consisting of a Public Switch Telephone Network(PSTN), a fiber optic communication link, a coaxial cable, a publicTCP/IP network, and a satellite communication link.
 19. The method ofclaim 1 further comprises establishing a communication path fortransmitting and receiving signals between a TSFD wireless device and anexternal network via a TSFD wireless device connected to the externalnetwork.
 20. The method of claim 19 wherein the external network isselected from the group consisting of a Public Switch Telephone Network(PSTN), a fiber optic communication link, a coaxial cable, a publicTCP/IP network, and a satellite communication link.
 21. The method ofclaim 1 further comprises establishing a communication path fortransmitting and receiving signals between a TSFD wireless device and alocal communication network.
 22. The method of claim 1 wherein thetransmitting and receiving signals further comprises a secondary mode ofoperation selected from the group consisting of wireless protocols andlandline protocols.
 23. The method of claim 22 wherein the wirelessprotocol is selected from the group consisting of AMPS, D-AMPS, IS-95,IS-136, and GSM1900.
 24. The method of claim 1 further comprisingoperating the TSFD wireless device in a secondary synchronous modetransmitting and receiving signals with a synchronous wireless device.25. A method of operating a parallel-configured Time-Shared Full Duplex(TSFD) wireless communication system for voice and data signals, thesystem comprising one or more macrocells and each macrocell having aplurality of microcells, and the method comprises: establishing a localcommunication path for transmitting and receiving signals between alocal TSFD wireless device and a remotely placed local TSFD wirelessdevice within a same microcell comprising: receiving and transmittingsignals between the local TSFD wireless device and a Parallel-configuredSignal Extender (PSE); receiving and transmitting signals between thePSE, the local TSFD wireless device and the remotely placed local TSFDwireless device; receiving and transmitting signals between the remotelyplaced local TSFD wireless device and the PSE; and operating the PSE byoperating first and second signal extenders in parallel and independentof each other yet sharing information with each other and upon failureof one of the first and second signal extenders the other one of thefirst and second signal extenders continues operation and maintainscommunications; establishing an extended communication path fortransmitting and receiving signals between an extended TSFD wirelessdevice and a remotely placed extended TSFD wireless device withindifferent microcells positioned within a same macrocell comprising:transmitting and receiving signals between die extended TSFD wirelessdevice and a first PSE; transmitting and receiving signals between thefirst PSE and a Parallel- configured Network Extender (PNE);transmitting and receiving signals between the PNE and a second PSE,transmitting and receiving signals between the second PSE and theremotely placed extended TSFD wireless device; transmitting andreceiving signals between the remotely placed extended TSFD wirelessdevice and the second PSE; and operating the PNE by operating first andsecond network extenders in parallel and independent of each other yetsharing information with each other and upon failure of one of the firstand second network extenders the other one of the first and secondnetwork extenders continues operation and maintains communications;establishing a distant communication path for transmitting and receivingsignals between a distant TSFD wireless device and a remotely placeddistant TSFD wireless device within different microcells positionedwithin different macrocells comprising: transmitting and receivingsignals between the distant TSFD wireless device and a first PSE;transmitting and receiving signals between the first PSE and a firstPNE; transmitting and receiving signals between the first PNE and asecond PNE; transmitting and receiving signals between the second PNEand a second PSE; transmitting and receiving signals between the secondPSE and the remotely placed distant TSFD wireless device; andtransmitting and receiving signals between the remotely placed distantTSFD wireless device and the second PSE; asynchronously transmitting andreceiving half duplex signals over the communication paths using pairsof assigned communication path frequencies stabilized by a GPS-basedfrequency reference source; monitoring and analyzing the communicationpaths by a system-resident and decentralized Parallel ComputingArtificial Intelligence-based Distributive Routing System; andre-directing the communication paths to ensure call loads of the PSE andPNE in the system do not exceed a predetermined limit for each PSE orPNE, to optimize call loads of the PSE and PNE in the system, or tobypass any failed PSE or PNE in the system; wherein the TSFD wirelessdevice is selected from the group consisting of: TSFD wireless handsets,TSFD wireless Personal Computer Data Communication Cards (TSFD wirelessPC-DatCom Cards), TSFD wireless Data Communication Modules (TSFDwireless DatComs), and TSFD wireless Communication Docking Bays (TSFDwireless ComDocs), and wherein the transmitting and receiving signalsbetween a TSFD wireless device or PSE or a PNE and another TSFD wirelessdevice or a PSE or PNE is conducted asynchronously with a primaryTime-Shared Full Duplex (TSFD) wireless protocol.
 26. The method ofclaim 25 wherein transmitting signals between the first PNE and thesecond PNE is selected from the group consisting of transmitting signalsover a Public Switch Telephone Network (PSTN), transmitting signals overa fiber optic communication link, transmitting signals over a coaxialcable, transmitting signals over a public TCP/IP network, andtransmitting signals over a satellite communication link.
 27. The methodof claim 25 wherein transmitting signals from the TSFD wireless deviceto the PSE is in a low radio frequency band and transmitting signalsfrom the PSE to the TSFD wireless device is in a high radio frequencyband, transmitting signals from the PSE to the PNE is in a high radiofrequency band and transmitting signals from the PNE to the PSE is inthe low radio frequency band, and transmitting signals between the PNEis on a high data rate system backbone.
 28. The method of claim 27wherein half of the signals received by a PSE in a microcell istransmitted by TSFD wireless devices in the microcell in a low radiofrequency band and half of the signals received by the PSE in amicrocell is transmitted by a PNE in the macrocell in a low radiofrequency band.
 29. The method of claim 25 wherein half of the signalstransmitted by a PSE in a microcell is received by TSFD wireless devicesin the microcell in a high radio frequency band and half of the signalstransmitted by the PSE in a microcell is received by a PNE in themacrocell in a high radio frequency band.
 30. The method of claim 25wherein transmitting and receiving signals comprises using FrequencyDivision Multiple Access techniques for determining sub-bands in thehigh and low radio frequency bands.
 31. The method of claim 25 whereintransmitting and receiving signals comprises using Gaussian MinimumShift Keying modulation for producing a radio frequency waveform. 32.The method of claim 25 wherein the transmitting and receiving signalsfurther comprises a secondary mode of operation selected from the groupconsisting of wireless protocols and landline protocols.
 33. The methodof claim 32 wherein the wireless protocol is selected from the groupconsisting of AMPS, D-AMPS, IS-95, IS-136, and GSM1900.
 34. The methodof claim 25 further comprises controlling an operational state of theTSFD wireless communication system by transmitting an operational statecommand to a PNE from the TSFD wireless device wherein the operationalstate command is a static operational command or a dynamic operationalcommand.
 35. The method of claim 25 wherein establishing a local voicecommunication path between a local TSFD wireless device and a remotelyplaced local TSFD wireless device may comprise using two fixedfrequencies in a sub-band spectrum for establishing a local voicechannel.
 36. The method of claim 25 wherein establishing a local datacommunication path under a four channel Contiguous Channel AcquisitionProtocol between a local TSFD wireless device and a remotely placedlocal TSFD wireless device comprises using two fixed frequencies havinga bandwidth of four times the bandwidth of a local voice channel bycombining four contiguous voice channels.
 37. The method of claim 25wherein establishing a local data communication path under a twelvechannel Contiguous Channel Acquisition Protocol Plus between a localTSFD wireless device and a remotely placed local TSFD wireless devicecomprises using two fixed frequencies having a bandwidth of twelve timesthe bandwidth of a local voice channel by combining twelve contiguousvoice channels.
 38. The method of claim 25 wherein establishing anextended voice communication path comprises using four fixed frequenciesin a sub-band spectrum for establishing an extended voice channel. 39.The method of claim 25 wherein establishing an extended datacommunication path under a four channel Contiguous Channel AcquisitionProtocol between an extended TSFD wireless device and a remotely placedextended TSFD wireless device comprises using four fixed frequencieshaving a bandwidth of four times the bandwidth of an extended voicechannel by combining four contiguous voice channels.
 40. The method ofclaim 25 wherein establishing an extended data communication path undera twelve channel Contiguous Channel Acquisition Protocol Plus between anextended TSFD wireless device and a remotely placed extended TSFDwireless device comprises using four fixed frequencies having abandwidth of twelve times the bandwidth of an extended voice channel bycombining twelve contiguous voice channels.
 41. The method of claim 25wherein establishing a distant voice communication path may compriseusing four fixed frequencies in a sub-band spectrum for establishing adistant voice channel.
 42. The method of claim 25 wherein establishing adistant data communication path under a four channel Contiguous ChannelAcquisition Protocol between a distant TSFD wireless device and aremotely placed distant TSFD wireless device comprises using four fixedfrequencies having a bandwidth of four times the bandwidth of a distantvoice channel by combining four contiguous voice channels.
 43. Themethod of claim 25 wherein establishing a distant data communicationpath under a twelve channel Contiguous Channel Acquisition Protocol Plusbetween a distant TSFD wireless device and a remotely placed distantTSFD wireless device comprises using four fixed frequencies having abandwidth of twelve times the bandwidth of a distant voice channel bycombining twelve contiguous voice channels.
 44. The method of claim 25further comprises establishing a communication path for transmitting andreceiving signals between a TSFD wireless device and an external networkvia another TSFD wireless device connected to the external network. 45.The method of claim 44 wherein the external network is selected from thegroup consisting of a Public Switch Telephone Network, a fiber opticcommunication link, a coaxial cable, a public TCP/IP network, and asatellite communication link.
 46. The method of claim 25 whereintransmitting signals comprises digitizing, buffering and encoding voiceframes and transmitting the voice frames in packets at a date rate thatis at least twice that required for real-time decoding, wherebytransmitting time requires less than half of real time, and receivingsignals may comprise receiving and decoding the voice frame packets at adata rate that is equal to that required for real-time decoding, wherebyreceiving time requires less than half of real-time.
 47. The method ofclaim 25 further comprises transmitting and receiving information over areference channel for providing a TSFD wireless device and another TSFDwireless device with time and date information, microcell and macrocellidentification code, attention codes, and broadcast text messages. 48.The method of claim 25 further comprises transmitting and receivinginformation over a call initiation channel for handling TSFD wirelessdevice and receiving Mobile TSFD wireless device initial registration,periodic registration, authorization and short identification (ID)assignment, call requests, call frequency assignment, call progressprior to voice and data channel use, and acknowledgement, wherein themethod may further comprise transmitting and receiving information overa call maintenance channel for call completion, call request, 911position report, call handoff frequency, call waiting notification,voice message notification, text message notification, andacknowledgement.
 49. The method of claim 25 further comprising operatingthe TSFD wireless device in a secondary synchronous mode transmittingand receiving signals with a synchronous wireless device.
 50. Aparallel-configured Time-Shared Full Duplex (TSFD) wirelesscommunication system for voice and data signals comprises: one or moremacrocells and each macrocell having a plurality of microcells; a TSFDwireless set comprising one or more TSFD wireless devices selected fromTSFD wireless handsets, TSFD wireless Communication Docking Bays (TSFDwireless ComDocs), TSFD wireless External Data Communication Modules(TSFD wireless X-DatComs), and TSFD wireless Personal Computer DataCommunication Cards (TSFD wireless PC-DatCom Cards); aParallel-configured TSFD Signal Extender (PSE) located in the microcell,the PSE having first and second signal extenders interfaced with eachother and operating independently of each other, the first and secondsignal extenders having a parallel configuration such that upon failureof one of the first and second signal extenders the other one of thefirst and second signal extenders continues to operate and maintaincommunications; a Parallel-configured TSFD Network Extender (PNE)located in the macrocell, the PNE having first and second networkextenders interfaced with each other and operating independently of eachother, the first and second network extenders having a parallelconfiguration such that upon failure of one of the first and secondnetwork extenders the other one of the first and second networkextenders continues to operate and maintain communications; means forestablishing a local communication path for transmitting and receivingsignals between a local TSFD wireless device and a remotely placed localTSFD wireless device within a same microcell via a PSE; means forestablishing an extended communication path for transmitting andreceiving signals between an extended TSFD wireless device and aremotely placed extended TSFD wireless device located within differentmicrocells positioned within a same macrocell via PSE and a PNE; meansfor establishing a distant communication path for transmitting andreceiving signals between a distant TSFD wireless device and a remotelyplaced distant TSFD wireless device located within different microcellspositioned within different macrocells via PSE and PNE; means forasynchronously transmitting and receiving half-duplex signals over thecommunication paths using pairs of assigned communication pathfrequencies stabilized by a GPS-based frequency reference source; and asystem-resident and decentralized Parallel Computing ArtificialIntelligence-based Distributive Routing System for monitoring andanalyzing the transmitted and received signals over the communicationpaths resulting in re-directing the communication paths to ensure callloads of the PSE and PNE in the system do not exceed a predeterminedlimit for each PSE or PNE, to optimize call loads of the PSE and PNE inthe system, or to bypass any failed PSE or PNE in the system; andwherein the transmitting and receiving signals between a TSFD wirelessdevice or PSE or a PNE and another TSFD wireless device or a PSE or PNEis conducted asynchronously with a primary Time-Shared Full Duplex(TSFD) wireless protocol.
 51. The system of claim 50, wherein the meansfor establishing a local communication path for transmitting andreceiving signals between a local TSFD wireless device and a remotelyplaced local TSFD wireless device within a same microcell via a PSEcomprises: a local TSFD wireless device; a PSE; a remotely placed localTSFD wireless device within the same microcell; wherein the local TSFDwireless device encodes voice and data frame packets and transmittingthese packets as radio frequency signals in a low radio frequency band;the PSE receives, amplifies, and shifts a frequency of the local TSFDwireless device and the local TSFD wireless devices' signals in the lowradio frequency band to a high radio frequency band and transmitting thehigh radio frequency band signals; the remotely placed local TSFDwireless device receives signals in the high radio frequency band fromthe PSE and decodes the received signals into a voice and data framepacket; the remotely placed local TSFD wireless device encodes voice anddata frame packet and transmits these packets as radio frequency signalsin a low radio frequency band; and the local TSFD wireless devicereceives signals in the high radio frequency band from the PSE anddecodes the received signals into a voice and data frame packet.
 52. Thesystem of claim 50 wherein the means for establishing an extendedcommunication path for transmitting and receiving signals between anextended TSFD wireless device and a remotely placed extended TSFDwireless device within different microcells positioned within a samemacrocell via PSE and a PNE comprises: an extended TSFD wireless device;a first PSE; a PSE; a second PSE; and a remotely placed extended TSFEwireless device; wherein the extended TSFD wireless device encodes voiceand data frame packet and transmits these packets as radio frequencysignals in a low frequency band; the first PSE receives, amplifies, andshifts a frequency of the extended TSFD wireless device signals in thelow radio frequency band to a high radio frequency band and transmittingthe high radio frequency band signals from the first PSE to the PNE; thePNE receives, amplifies, and shifts a frequency of PSE signals in thehigh radio frequency band to a low radio frequency band and transmittingthe low radio frequency band signals from the PNE to selected PSEs; thesecond PSE receives, amplifies, and shifts a frequency of the PNEsignals in the low frequency band to a high radio frequency band andtransmits the high radio frequency band signals; the remotely placedextended TSFD wireless device receives the second PSE signals in thehigh radio frequency band and decodes the received signals into a voiceand data frame packet; the remotely placed extended TSFD wireless deviceencodes voice and data frame packet and transmits these packets as radiofrequency signals in a low frequency band; the second PSE receives,amplifies, and shifts a frequency of the TSFD wireless handset signalsin the low radio frequency band to a high radio frequency band andtransmitting the high radio frequency band signals from the second PSEto the PNE; the first PSE receives, amplifies, and shifts a frequency ofthe PNE signals in the low frequency band to a high radio frequency bandand transmits the high radio frequency band signals; and the extendedTSFD wireless device receives the first PSE signals in the high radiofrequency band and decodes the received signals into a voice and dataframe packet.
 53. The system of claim 50 wherein the means forestablishing a distant communication path for transmitting and receivingsignals between a distant TSFD wireless device and a remotely placeddistant TSFD wireless device within different microcells positionedwithin different macrocells via PSEs and PNEs comprises: a distant TSFDwireless device; a remotely placed distant TSFD wireless device withindifferent microcells positioned within different macrocells; a firstPNE; a first PSE; a second PNE; and a second PSE; wherein the first PNEreceives, amplifies first PSE signals from a first PSE and transmits thefirst PSE signals to a second PNE over a dedicated communication link;and the second PNE receives and shifts a frequency of first PSE signalsin the high radio frequency band to a low radio frequency band andtransmitting the low radio frequency band signals from the second PNE tothe second PSE.
 54. The system of claim 50 wherein the TSFD wirelessdevice further comprises external communication paths for transmittingand receiving signals between the TSFD wireless device and an externalcommunication network to enable TSFD wireless device and devicesassociated with another TSFD wireless device to connect to the externalnetwork through the TSFD wireless device.
 55. The system of claim 54wherein the external network is selected from the group consisting of aPublic Switch Telephone Network, a fiber optic communication link, acoaxial cable, a public TCP/IP networks and a satellite communicationlink.
 56. The system of claim 50 wherein the TSFD wireless devicefurther comprises local communication paths for transmitting andreceiving signals between the TSFD wireless device and a localcommunication network.
 57. The system of claim 50 further comprisesusing a secondary mode of operation selected from the group of wirelessprotocols and landline protocols.
 58. The system of claim 57 wherein thewireless protocol is selected from the group consisting of AMPS, D-AMPS,IS-95, IS-136, and GSM1900.
 59. The system of claim 50 wherein: amicrocell comprises a geographical area containing one or more wirelessdevices and a PSE; and a macrocell comprises a geographical areacontaining between one and twenty one microcells, and a PNE.
 60. Thesystem of claim 50 wherein the TSFD wireless device comprises: aprocessor for controlling TSFD wireless device operation comprising adigital signal processor, a controller, and memory; a user interfacecomprising a display, a keypad, visual indication or, audio annunciator,microphone and speaker, a vocoder connected to a microphone and speakerinterface; a power manager, battery and power source; an external datainterface; connections for fixed telephone handset extensions;connections to a Public Switch Telephone Network; a primary modetransceiver having a transmitter and two receivers connected to anomni-directional antenna for use with a TSFD protocol; and an optionalsecondary mode transceiver for providing service using another standardprotocol selected from the group consisting of wireless protocols andlandline protocols.
 61. The system of claim 60 wherein the wirelessprotocol is selected from the group consisting of AMPS, D-AMPS, IS-95,IS-136, and GSM1900.
 62. The system of claim 50 wherein the TSFDwireless device includes an optional interface connection to an infrareddata interface, an external keyboard interface, an external monitorinterface, a video camera interface, A Wireless Fidelity (WiFi) Link, aRed Fang link, a Bluetooth interface, a LAN/cable modem interface, anenhanced 911 (E-911) position locator interface, a GPS position locatorinterface, a hard drive interface, a CD/DVD drive interface, a PublicSwitch Telephone Network modem interface, or an external antennainterface.
 63. The system of claim 50 wherein the TSFD wireless devicetransmits voice and data packets half of the time and receives voice anddata packets half of the time when in use.
 64. The system of claim 50wherein a TSFD wireless device communicates directly with another TSFDwireless device using the TSFD wireless protocol without communicatingvia a signal or network extender.
 65. The system of claim 50 wherein theTSFD wireless device has a secondary synchronous mode that transmits andreceives signals with a synchronous wireless device.